Method and means for improving bowel health

ABSTRACT

A method and composition for improving one or more indicators of bowel health or metabolic health in a mammalian animal. This comprises the delivering to the gastrointestinal tract of the animal an effective amount of an altered wheat starch in the form of or derived from the grain of a wheat plant. The proportion of amylose in the starch of the grain is at least 30%.

This application is a continuation-in-part of U.S. Ser. No. 11/324,063, now U.S. Pat. No. 7,700,139 filed Dec. 30, 2005, which claims the benefit of U.S. Provisional Application No. 60/688,944, filed Jun. 8, 2005, and claims priority of Australian Provisional Application No. 2004907350, filed Dec. 30, 2004, the contents of all of which are hereby incorporated by reference into this application.

FIELD OF THE INVENTION

This invention relates to methods of improving the health of mammals including humans by the use of diets including modified wheat. The invention also relates to wheat products with properties including increased levels of resistant starch or a high relative amylose content that provide for improved bowel health.

BACKGROUND OF THE INVENTION

Serious non-infectious chronic illnesses relating to diet and lifestyle are major causes of morbidity and mortality in affluent industrialised countries and also in emerging ones with greater affluence. These include coronary heart disease, diverticular disease, certain cancers (especially of the colon and rectum) and diabetes. Cereal foods have significant potential to improve human health through lowering the risk of these conditions. The benefits may be obtained through consumption of processed foods containing whole grains or their constituents including complex carbohydrates—starch and non-starch polysaccharides (NSP, major components of dietary fibre). NSP are resistant to digestion by human small intestinal enzymes which helps to explain their effectiveness in increasing faecal bulk and relieving constipation (Topping & Clifton, 2001). While starch can be digested (theoretically to completion) in the human small intestine, some escapes into the large bowel. This fraction is resistant starch (RS) which, together with a variable fraction of NSP, is metabolised by the large bowel microflora (Topping & Clifton, 2001). Short chain fatty acids (SCFA) are major end products of this fermentation and they promote important aspects of large bowel function-stimulation of fluid and electrolyte absorption, modulation of muscular contraction and visceral perfusion (Topping & Clifton, 2001). One of the principal SCFA, butyrate, may also play a role in promoting a normal phenotype in colonocytes, and enhancing normally controlled colonocyte proliferation and lowering the risk of colo-rectal cancer. The latter malignancy is a substantial cause of early morbidity in affluent industrialised countries. A further consequence of slower starch small intestinal digestibility is the potential to lower the rate of entry of glucose into the circulation and, thus, a lesser demand for insulin. This is measured as glycaemic index (GI) which is emerging as a substantial factor in disease risk.

It is emerging also that many of the actions ascribed to dietary fibre may actually be due to RS (Topping & Clifton, 2001). RS intakes are low in populations at high risk of the diseases of affluence and modification of convenience foods to enhance the content and action of RS is considered to be an effective means of improving nutrition for public health at the population level. This may be put into practice through encouraging the consumption of specific foods, such as beans or wholegrain (brown) rice, which are intrinsically high in RS. Another approach is to enrich convenience foods with RS as an added ingredient.

Wheat is a staple food in many countries and supplies approximately 20% of the food kilojoules for the total world population. The processing characteristics of wheat make it the preferred base for most cereal-based processed products such as bread, pasta and noodles. Wheat consumption is increasing world-wide with increasing affluence. Breadwheat (Triticum aestivum) is a hexaploid having three different genomes, A, B and D, and most of the known genes in wheat are present in triplicate, one on each genome. The hexaploid nature of the breadwheat genome makes finding and combining gene mutations in each of the three genomes a challenge. The presence of three genomes has a buffering effect by masking mutations in individual genomes, in contrast to the more readily identified mutations in diploid species. Known variation in wheat starch structure has been limited relative to the variation available in maize or rice. Another contributing factor to this is that the transformation efficiency of wheat has lagged behind that for other cereals.

The synthesis of starch in the endosperm of higher plants is carried out by a suite of enzymes that catalyse four key steps. Firstly, ADP-glucose pyrophosphorylase activates the monomer precursor of starch through the synthesis of ADP-glucose from G-1-P and ATP. Secondly, the activated glucosyl donor, ADP-glucose, is transferred to the non-reducing end of a pre-existing α1-4 linkage by starch synthases. Thirdly, starch branching enzymes introduce branch points through the cleavage of a region of α-1,4 linked glucan followed by transfer of the cleaved chain to an acceptor chain, forming a new α-1,6 linkage. Starch branching enzymes are the only enzymes that can introduce the α-1,6 linkages into α-polyglucans and therefore play an essential role in the formation of amylopectin. Finally, starch debranching enzymes remove some of the branch linkages although the mechanism through which they act is unresolved (Myers et al., 2000).

While it is clear that at least these four activities are required for normal starch granule synthesis in higher plants, multiple isoforms of each of the four activities are found in the endosperm of higher plants and specific roles have been proposed for individual isoforms on the basis of mutational analysis (Wang et al, 1998, Buleon et al., 1998) or through the modification of gene expression levels using transgenic approaches (Abel et al., 1996, Jobling et al., 1999, Scwall et al., 2000). However, the precise contributions of each isoform of each activity to starch biosynthesis are still not known, and it is not known whether these contributions differ markedly between species. In the cereal endosperm, two isoforms of ADP-glucose pyrophosphorylase are present, one form within the amyloplast, and one form in the cytoplasm (Denyer et al., 1996, Thorbjornsen et al., 1996). Each form is composed of two subunit types. The shrunken (sh2) and brittle (bt2) mutants in maize represent lesions in large and small subunits respectively (Giroux and Hannah, 1994). Four classes of starch synthase are found in the cereal endosperm, an isoform exclusively localised within the starch granule, granule-bound starch synthase (GBSS), two forms that are partitioned between the granule and the soluble fraction (SSI, Li et al., 1999a, SSII, Li et al., 1999b) and a fourth form that is entirely located in the soluble fraction, SSIII (Cao et al, 2000, Li et al., 1999b, Li et al, 2000). GBSS has been shown to be essential for amylose synthesis (Shure et al., 1983), and mutations in SSII and SSIII have been shown to alter amylopectin structure (Gao et al, 1998, Craig et al., 1998). No mutations defining a role for SSI activity have been described.

Three forms of branching enzyme are expressed in the cereal endosperm, branching enzyme I (SBEI), branching enzyme IIa (SBEIIa) and branching enzyme IIb (SBEIIb) (Hedman and Boyer, 1982, Boyer and Preiss, 1978, Mizuno et al., 1992, Sun et al., 1997). Genomic and cDNA sequences have been characterized for rice (Nakamura and Yamanouchi, 1992), maize (Baba et al., 1991; Fisher et al., 1993; Gao et al., 1997) and wheat (Repellin et al., 1997; Nair et al., 1997; Rahman et al., 1997). Sequence alignment reveals a high degree of sequence similarity at both the nucleotide and amino acid levels and allows the grouping into the SBEI, SBEIIa and SBEIIb classes. SBEIIa and SBEIIb generally exhibit around 80% sequence identity to each other, particularly in the central regions of the genes. SBEIIa and SBEIIb may also be distinguished by their expression patterns. SBEIIb in maize is specifically expressed in endosperm while SBEIIa is present in every tissue of the plant.

In wheat endosperm, SBEI (Morell et al, 1997) is found exclusively in the soluble fraction, while SBEIIa and SBEIIb are found in both soluble and starch-granule associated fractions (Rahman et al., 1995). In maize and rice, high amylose phenotypes have been shown to result from lesions in the SBEIIb gene, also known as the amylose extender (ae) gene (Boyer and Preiss, 1981, Mizuno et al., 1993; Nishi et al., 2001). In these SBEIIb mutants, endosperm starch grains showed an abnormal morphology, amylose content was significantly elevated, the branch frequency of the residual amylopectin was reduced and the proportion of short chains (<DP17, especially DP8-12) was lower. Moreover, the gelatinisation temperature of the starch was increased. In addition, there was a significant pool of material that was defined as “intermediate” between amylose and amylopectin (Boyer et al., 1980, Takeda, et al., 1993b). In contrast, maize plants mutant in the SBEIIa gene due to a mutator (Mu) insertional element and consequently lacking in SBEIIa protein expression were indistinguishable from wild-type plants in the branching of endosperm starch (Blauth et al., 2001), although they were altered in leaf starch. Similarly, rice plants deficient in SBEIIa activity exhibited no significant change in the amylopectin chain profile in endosperm (Nakamura 2002). In both maize and rice, the SBEIIa and SBEIIb genes are not linked in the genome.

Mutations in wheat SBEIIa or SBEIIb or the phenotypes of wheat lines carrying these mutations have not been reported. Known mutants in wheat are for the waxy gene (GBSS, Zhao and Sharp, 1998) and a mutant entirely lacking the SGP-1 protein (Yamamori et al, 2000) which was produced by crossing lines which were lacking the A, B and D genome specific forms of SGP-1 (SSII) protein as assayed by protein electrophoresis. Examination of the SSII null seeds showed that the mutation resulted in alterations in amylopectin structure, deformed starch granules, and an elevated relative amylose content to about 30-37% of the starch, which was an increase of about 8% over the wild-type level (Yamamori et al., 2000). Amylose was measured by colorimetric measurement, amperometric titration (both for iodine binding) and a concanavalin A method. Starch from the SSII null mutant exhibited a decreased gelatinisation temperature compared to starch from an equivalent, non-mutant plant. Starch content was reduced from 60% in the wild-type to below 50% in the SSII-null grain.

In maize, the dull1 mutation causes decreased starch content and increased amylose levels in endosperm, with the extent of the change depended on the genetic background, and increased degree of branching in the remaining amylopectin (Shannon and Garwood, 1984). The gene corresponding to the mutation was identified and isolated by a transposon-tagging strategy using the transposon mutator (Mu) and shown to encode the enzyme designated starch synthase II (SSII) (Gao et al., 1998). The enzyme is now recognized as a member of the SSIII family in cereals (Li et al., 2003). Mutant endosperm had reduced levels of SBEIIa activity associated with the dull1 mutation. No corresponding mutation has been reported in other cereals. It is not known if these findings are relevant to other cereals, for example wheat.

Two types of debranching enzymes are present in higher plants and are defined on the basis of their substrate specificities, isoamylase type debranching enzymes, and pullulanase type debranching enzymes (Myers et al., 2000). Sugary-1 mutations in maize and rice are associated with deficiency of both debranching enzymes (James et al., 1995, Kubo et al., 1999) however the causal mutation maps to the same location as the isoamylase-type debranching enzyme gene. Representative starch branching enzyme sequences from genes that have been cloned from cereals are listed in Table 1.

TABLE 1 Starch branching enzyme genes characterized from cereals. Type of Species SBE isoform clone Accession No. Reference Wheat SBEI cDNA and AJ237897 SBEI gene) Baga et al., 1999 genomic AF002821 (SBEI pseudogene Rahman et al., 1997, AF076680 (SBEI gene) Rahman et al., 1999 AF076679 (SBEI cDNA) SBEI cDNA Y12320 Repellin et al., 1997 SBEIIa cDNA Y11282 Nair et al., 1997 SBEIIa cDNA and AF338432 (cDNA) Rahman et al., 2001 genomic AF338431 (gene) SBEIIb cDNA and WO 01/62934 genomic SBEIIb cDNA WO 00/15810 Rice SBEI cDNA D10752 Nakamura and Yamanouchi, 1992 SBEI genomic D10838 Kawasaki et al., 1993 RBE3 cDNA D16201 Mizuno et al., 1993 Barley SBEIIa and cDNA and AF064563 (SBEIIb gene) Sun et al., 1998 SBEIIb genomic AF064561 (SBEIIb cDNA) AF064562 (SBEIIa gene) AF064560 (SBEIIa cDNA) Maize SBEI cDNA U17897 Fisher et al., 1996 genomic AF072724 Kim et al., 1998a SBEIIb cDNA L08065 Fisher et al., 1993 genomic AF072725 Kim et al., 1998 SBEIIa cDNA U65948 Gao et al., 1997

Starch composition, in particular the form called resistant starch which may be associated with high amylose content, has important implications for bowel health, in particular health of the large bowel. The beneficial effects of resistant starch are thought to result from the provision of a nutrient to the large bowel wherein the intestinal microflora are given an energy source which is fermented to form inter alia short chain fatty acids. These short chain fatty acids provide nutrients for the colonocytes, enhance the uptake of certain nutrients across the large bowel and promote physiological activity of the colon. Generally if resistant starches or other dietary fibre are not provided the colon is metabolically relatively inactive.

Whilst chemically or otherwise modified starches can be utilised in foods that provide functionality not normally afforded by unmodified sources, such processing has a tendency to either alter other components of value or carry the perception of being undesirable due to processes involved in modification. Therefore it is preferable to provide sources of constituents that can be used in unmodified form in foods. Although high amylose maize and barley varieties are known, products from these cereals have disadvantages compared to a very high amylose wheat for products where wheat is the preferred cereal, for example in bread, pasta or noodles. There is therefore an opportunity for a large scale improvement in public health including bowel health and metabolic health through the alteration of wheat starch, which may provide an increase in resistant starch and reduction in glycemic index when provided in the diet.

On passage from the ileum, resistant starches are metabolised by the anaerobic microflora of the caecum and colon which produce the enzymes necessary for polysaccharide hydrolysis and catabolism. Breakdown is effected by bacterial species very similar to those found in the rumen of obligate herbivores and with very similar products: gases, such as carbon dioxide, methane and hydrogen, and short chain fatty acids (SCFA). The principle SCFA formed are acetate, propionate and butyrate in the rough molar proportions 60:20:20. These three acids contribute some 80-90% of total colonic SCFA, the remainder being branched chain and other fatty acids formed from the breakdown of dietary and endogenous protein. Animals fed resistant starch have shown higher colonic SCFA and in some cases increased bacterial mass in the colon. Many of the effects of resistant starch in the colon are probably mediated through SCFA.

The role of dietary fibre in the prevention and management of simple constipation is beyond question. Fibres vary in their effects on bowel function. Cereal brans such as wheat and rice brans that are high in insoluble NSP appear to be most effective in easing problems of Taxation through shortening transit time, softening stools through raised water holding, increasing stool volume and weight in the form of bacteria and undigested and non-fermentable material.

Although it is convenient to explain the actions of fibre-rich foods such as wheat bran solely in terms of stool mass, this is not quite correct. However, the increase in faecal bulk in humans eating mixed diets is considerably higher than predicted from their non starch polysaccharide content—the “carbohydrate gap” (Stephen (1991) Can J Physiol. Pharmacol. 69:116-20). Starch is thought to fill this gap and contribute to the greater faecal bulk through bacterial proliferation, by providing a fermentation substrate, (both glucose, and certain SCFA) as well as providing physical bulk.

Increases in microbial mass from undigestible carbohydrate fermentation contributes directly to stool bulk, which is a large part of the stool weight. Bacteria are about 80% water and have the ability to resist dehydration, as such they contribute to water-holding in fecal material. The number of bacteria in human feces is approximately 4×10¹¹-8×10¹¹/g dry feces, and makes up to about 50% of fecal solids in subjects on a Western diet. Gas production from colonic fermentation can also have some influence on stool bulk. Trapping of gas can contribute to increased volume and a decrease in fecal transit time.

The metabolic end products of fermentation, namely the gases, SCFA and increased microflora play a pivotal role in the physiological effects of the undigestible carbohydrate in the colon and implications for local effects in the colon and systemic effects. The gases produced from fermentation by strict anaerobic species such as bacteriodes, some non-pathogenic species of clostridia and yeasts, anaerobic cocci and some species of lactobacilli are mostly released as flatulence or are absorbed and subsequently lost from the body through the lungs. However, some of the hydrogen and carbon dioxide produced from these microflora may be further metabolized to methane (CH₄) by methanogenic bacteria, thus reducing intestinal gas pressure. Of these anaerobic microorganisms, the clostridia, eubacteria and anaerobic cocci are the most gas producing, while the bifidobacteria are the only group of common gut microflora that do not produce any gases.

Because resistant starch is not digested or absorbed, it also serves as a prebiotic for beneficial bacteria, such as bifidobacteria and lactobacilli. Multiplying beneficial bacteria reduce the pH level in the colon, making the environment uninhabitable for potentially harmful bacteria such as E. coli, clostridia, Veillonella and Klebsiella. The proliferation of beneficial bacteria provides significant health effects, including enhanced digestion and improved lactose intolerance, promoting the recycling of compounds such as estrogen, synthesizing vitamins, especially B-group vitamins, producing immune-stimulating compounds, inhibiting the growth of harmful bacteria, reducing the production of toxins and carcinogens, restoring normal intestinal bacteria during antibiotic therapy, and reducing the potential for several pathologies commonly associated with higher numbers of pathogenic intestinal bacteria. These include autoimmune illnesses such as ankylosing spondylitis and rheumatoid arthritis, certain cancers, yeast overgrowth, vaginitis, urinary tract infections, cirrhosis of the liver, food poisoning, antibiotic-associated diarrhea, inflammatory bowel diseases such as ulcerative colitis and Crohn's disease, necrotizing entercolitis and ileocecitis, food allergy and intolerance, intestinal gas and bloating, and irritable bowel syndrome.

The primary SCFA generated by fermentation are acetate, propionate and butyrate, accounting for 83-95% of the total SCFA concentration in the large intestine, which ranges from about 60-150 μmol/L. The concentrations of these acids are highest where concentrations of microflora are also highest, namely in the cecum and right or transverse colon. Corresponding to these higher acid levels, the pH is also typically lowest in the transverse colon (5.4-5.9) and gradually increases through the distal colon to 6.6-6.9. As the pH is reduced, the colonic environment becomes less favorable for toxin-producing and ill-health promoting microflora, such as E. coli, clostridia, and certain yeasts.

The pH range of digesta in the human colon needs to be established but in pigs on high fibre diets it ranges from approximately 6 in the proximal colon to >7 in the distal colon. The pKa of short chain fatty acids is <4.8 so that in the colon they are present largely as anions. SCFA are absorbed in the non-ionic form and are then ionized at intracellular pH to H⁺ and SCFA which are then exchanged for luminal Na⁺ and Cl⁻ respectively. Some of the SCFA are also metabolized to HCO₃ which is also exchanged for chloride ions. Therefore SCFA is beneficial in facilitating transporting ions that play an important role in metabolism.

Thus SCFA do not contribute to osmotic load to any great extent and may ameliorate diarrhoea through removal of sodium and water from the colonic lumen. However, because SCFA are present largely as anions, their absorption is relatively slow. For this reason and their presence in faeces, SCFA have been assumed to cause diarrhoea. That view is no longer held and diarrhoea is thought to occur only when the osmotic pressure of simple and complex carbohydrates in the colon raises the fluid volume excessively and bacteria cannot break down the carbohydrate sufficiently rapidly. In fact SCFA may have longer term preventative effects by stimulating growth of colonocytes thereby increasing the capacity of the colon.

Epidemiological data have shown that the level of dietary fibre is inversely related to incidence of bowel cancer and a meta-analysis of a large number of studies showed that fibre was protective in over 50%. It is not possible to discriminate the type of NSP or foods that were effective. A study by Cassidy et al (British Journal of Cancer 69; 937-942 (1994)) has shown that starch plays a protective role.

The role of fibre in the maintenance of colonic mucosal integrity is understood imperfectly. Experiments with animal models such as pigs have shown that the weight and thickness of the colon is increased with diets high in fibre—consistent with greater cell growth. The effect is not confined to fibre as Goodlad and Mathers ((1990) Brit J Nutr. 64; 569-587) have obtained similar increases in the hindgut of rats fed diets high in resistant starch. Other studies with rats have shown that the increase is probably not due to increased mass of digesta since an inert faecal bulking agent (kaolin) did not stimulate mucosal proliferation. In the same experiments it was shown that colonic infusion of short chain fatty acids enhanced colonocyte proliferation suggesting that they were the trophic agents (Sakata J. Nutr Sci Vitaminol 1986; 32: 355-362). It is likely that only propionate and butyrate are involved in these effects. Propionate is known to enhance colonic motility possibly through stimulating blood flow (Kvietis and Granger, Gastroenterol (1981); 80:962-969). Butyrate is thought to play a most critical role in the cell biology of colonocytes and is preferred over acetate and propionate as their oxidative fuel (Cummings, Gut (1981) 22:763-779). Butyrate inhibits the proliferation of malignant cells from the human colon in vitro via inhibition of DNA synthesis and arresting of the cells in the G_(I) phase. Induction of cell differentiation has also been demonstrated, an observation that is consistent with the fact that when cells differentiate they lose their capacity to proliferate. Butyrate also enhances the capacity of colonic cells to repair DNA damage (Smith, Carcinogenesis (1986) 7:423-429). All of these effects require physical presence of the acid and are obtained at butyrate concentrations similar to those found in the colon in vivo. A particular point of interest is that there is evidence that human faecal inocula ferment starch to butyrate (Pilch (ed) Physiological effects and health consequences of dietary fibre. Bethesda Md. USA: FASEB 1987) and such production might explain inconsistencies in epidemiological data where fibre is not always protective but plant foods are beneficial.

Several studies in animal models have shown that supplementation of the diet with fibre protects against tumours induced with chemical carcinogens such as dimethylhydrazine (DMH), azoxymethane (AOM), and 3,2-dimethyl-4-aminobiphenyl (DMAB). Meta-analysis of these studies by the Federation of American Societies for Experimental Biology (FASEB) (Pilch (1987) supra) showed that wheat bran was more effective than pectin or cellulose in reducing lesion formation induced by chemical carcinogens. These data are paradoxical if one considers that soluble NSP might be expected to be fermented to SCFA more than wheat bran. However, rat studies show that wheat bran gives relatively higher concentrations of butyrate in hind-gut digesta than soluble NSP. In addition, wheat bran seems to bind chemical carcinogens and to reduce their colonic concentration and might be doing so in the animal model systems. A protective action of wheat against experimental carcinogenesis cannot be dismissed.

It is believed that butyrate enhances the proliferation of normal cells but may exert antineoplastic effects on susceptible cells and significantly retards the growth of human colon cancer cells in vitro (Kim et al In Malt and Williams (Eds) Colonic carcinogenesis. Lancaster MTP Press, (192); Falk Symposium 31: 317-323). A recent study which has shown that the molar proportion of butyrate is significantly lower in faeces from patients with adenomatous polyps (Weaner et al Gut (1988); 29: 1539-1543) is of special interest as it suggests that short chain fatty acid production is abnormal. In a feeding trial in patient with polyposis, a wheat bran supplement appeared to reduce polyp numbers and size (De Cosse et al J Nat Cancer Inst. (1989); 81:1290-1297). This is also a very promising study and indicates that insoluble NSP may be protective. Of particular interest is the fact in this study an insoluble NSP (which also enhances lactation) was protective. The situation with soluble NSP and resistant starch is unknown.

It is suggested that lack of luminal SCFAs lead in the short term to muscular atrophy and in the long term to ‘nutritional colitis’. This is especially evident in diversion colitis, which develops after complete diversion of the faecal stream and subsides after restoration of colorectal continuity. Irrigation with SCFA for 2-3 weeks has resulted in resolution of inflammation. Ulcerative colitis has also been successfully treated using butyrate enemas. (Scheppach et al (1992) Gasteroenterology; 103:51-56. Generally anti-inflammatory measures, such as the use of anti inflammatory drugs, do have side effects and in particular where large doses are used to overcome the natural degradation of those drugs in the small intestine before they reach the colon. The use of SCFA on the other hand is seen as particularly beneficial because they are naturally occuring and replace the use of anti-inflammatory drugs such as NSAIDS, corticosteroids and other anti inflammatory drugs.

General

Those skilled in the art will be aware that the invention described herein is subject to variations and modifications other than those specifically described. It is to be understood that the invention described herein includes all such variations and modifications. The invention also includes all such steps, features, compositions and compounds referred to or indicated in this specification, individually or collectively, and any and all combinations of any two or more of said steps or features.

Throughout this specification, unless the context requires otherwise the word “comprise”, and variations such as “comprises” and “comprising”, will be understood to imply the inclusion of a stated integer or step or group of integers or steps but not the exclusion of any other integer or step or group of integers or steps. The present invention is not to be limited in scope by the specific embodiments described herein, which are intended for the purposes of exemplification only. Functionally-equivalent products, compositions and methods are clearly within the scope of the invention, as described herein.

Bibliographic details of the publications referred to by the inventors in this specification are collected at the end of the description. The references mentioned herein are hereby incorporated by reference in their entirety. Reference herein to prior art, including any one or more prior art documents, is not to be taken as an acknowledgment, or suggestion, that said prior art is common general knowledge in Australia or forms a part of the common general knowledge in Australia.

As used herein, the term “derived from” shall be taken to indicate that a particular integer or group of integers has originated from the species specified, but has not necessarily been obtained directly from the specified source.

The designation of nucleotide residues referred to herein are those recommended by the IUPAC-IUB Biochemical Nomenclature Commission, wherein A represents Adenine, C represents Cytosine, G represents Guanine, T represents Thymidine.

SUMMARY OF THE INVENTION

This invention results from a finding that products made from the grain obtained from modified wheat plants comprise sufficient resistant starch and/or lowered glycemic index to provide a health benefit when ingested at levels which can be incorporated into food or beverage products or otherwise delivered to the gastrointestinal tract of a mammal. The health benefit may relate to bowel health or metabolic health or both.

In a first aspect the invention provides a method of improving one or more indicators of bowel health or metabolic health in a mammalian animal, comprising the step of delivering to the gastrointestinal tract of said animal an effective amount of an altered wheat starch in the form of or derived from the grain of a wheat plant, wherein the proportion of amylose in the starch of the grain is at least 30%. In a preferred embodiment, said grain comprises a reduced level of enzyme activity and/or protein of starch synthase IIa enzyme or a starch branching enzyme in the endosperm. The starch branching enzyme may be SBEIIa or both SBEIIa and SBEIIb. It will be understood that the levels are reduced relative to wild-type grain. In an embodiment, the grain comprises one or more genetic variations which lead to a reduction in the level of the starch synthase and/or starch branching enzyme gene expression, starch synthase and/or starch branching enzyme activity in the endosperm or both relative to wild-type grain, which genetic variation comprises a mutation of a starch synthase and/or starch branching enzyme gene or an introduced nucleic acid which encodes an inhibitor of starch synthase and/or starch branching enzyme gene expression. In a further embodiment, the grain comprises one or more genetic variations which lead to a reduced level of enzyme activity and/or protein in the endosperm of SSIIa, SBEIIa, or SBEIIa and SBEIIb relative to wild-type grain, which genetic variations comprise one or more mutations in genes encoding SSIIa, SBEIIa, or SBEIIa and SBEIIb, respectively, and/or one or more introduced nucleic acids which encode inhibitors of expression of genes encoding SSIIa, SBEIIa, or SBEIIa and SBEIIb.

The wheat plant may additionally comprise an altered, preferably reduced, level of SBEI protein, enzyme activity or both relative to wild-type grain. The wheat plant may additionally comprise an altered level of an enzyme relative to wild-type grain, wherein said enzyme is ADP glucose pyrophosphorylase, GBSS, SSI, SSIII, phosphorylase, a debranching enzyme of an isoamylase type, or a debranching enzyme of a pullulanase type, or any combination of these. The altered level may be an increased level or a decreased level.

The proportion of amylose in the starch of the grain may be at least 30%, more preferably at least 35%, at least 40%, at least 45%, at least 50% or at least 55%.

The altered wheat starch may comprise at least 2%, at least 2.5% or at least 3% resistant starch.

The amylopectin of the grain may be characterised in comprising a reduced proportion of the 4-12 dp chain length fraction relative to the amylopectin of wild-type grain, as measured after isoamylase debranching of the amylopectin.

The wheat plant or altered wheat starch may be any one or more of the forms described herein. It is thought that at least some of the altered wheat starch is a resistant starch. The altered wheat starch may be blended with unaltered wheat starch in the form of grain, flour, wholemeal, purified starch or other forms, or similarly with non-wheat starch or other food ingredients.

At least 10 g of altered wheat starch may be provided to a human per day although the levels are preferably greater than 15, 20, 25, 30, 35, 40, 45, 50 or 55 g per day. However the invention may also encompass levels of delivery as low as at least 1, 2 or 5 grams per day, or levels of delivery higher such as at least 60, 70, 80, or 100 grams per day.

The mammalian animal may be non-ruminant or monogastric, for example a human. The altered wheat starch is preferably delivered to the mammal, particularly humans, orally. The starch may be delivered in the form of whole grain or milled, ground, pearled, rolled, kibbled, par-boiled or cracked grain, or as isolated starch or starch granules. Alternatively the starch may be delivered as part of a food or beverage product which may be as a condiment. In a further alternative, the starch may be delivered in the form of a pharmaceutical preparation suitable for oral ingestion. It will be understood that whilst oral ingestion is preferred, the invention also encompasses other means of delivery of the altered wheat starch to the colon.

It may be advantageous also to modify the altered starch chemically. Chemical modification may include etherification, esterification, acidification, or reducing enzyme susceptibility by, for example, acid or enzyme thinning and cross bonding using difunctional reagents. Physical modification may include heating and crystallization. Such modifications may increase the level of resistant starches.

The indicators of improved bowel health may comprise, but are not necessarily limited to:

i) decreased pH of the bowel contents,

ii) increased total SCFA concentration or total SCFA amount in the bowel contents,

iii) increased concentration or amount of one or more SCFAs in the bowel contents,

iv) increased fecal bulk,

v) increase in total water volume of bowel or faeces, without diarrhea,

vi) improved Taxation,

vii) increase in number or activity of one or more species of probiotic bacteria,

viii) increase in fecal bile acid excretion,

ix) reduced urinary levels of putrefactive products,

x) reduced fecal levels of putrefactive products,

xi) increased proliferation of normal colonocytes,

xii) reduced inflammation in the bowel of individuals with inflamed bowel,

xiii) reduced fecal or large bowel levels of any one of urea, creatinine and phosphate in uremic patients, or

xiv) any combination of the above.

The pH of the bowel contents may be reduced by at least 0.1 pH unit, preferably at least 0.2 pH units, relative to the pH of the bowel contents when delivering to the gastrointestinal tract of the animal the corresponding amount and form of unaltered wheat starch, having less than 30% amylose in the starch. The one or more SCFA may be selected from formate, acetate, propionate, butryate, succinate or branched forms thereof, but is preferably one of acetate, proprionate and butyrate and more preferably butyrate.

Among the probiotic bacteria, bifidobacteria species are the most prominent. Lactic acid bacteria are similarly included such as, for example, Lactobacillus bulgaricus, Lactobacillus acidophilus, Lactobacillus casei, Lactobacillus plantarum, or Streptococcus faecium or Streptococcus thermophilus.

The indicators of improved metabolic health may comprise, but are not necessarily limited to:

i) stabilisation of post-prandial glucose fluctuation,

ii) improved (lowered) glycemic response,

iii) reduced pro-prandial plasma insulin concentration,

iv) improved blood lipid profile,

v) lowering of plasma LDL cholesterol,

vi) reduced plasma levels of one or more of urea, creatinine and phosphate in uremic patients,

vii) an improvement in a dysglucaemic response, or

viii) any combination of the above.

The improvement in each bowel health or metabolic health parameter as described herein is to be understood to be relative to the corresponding parameter when unaltered wheat starch is used, i.e. when a corresponding amount and form of wild-type wheat starch is delivered to the gastrointestinal tract of the animal, said wild-type wheat starch having a proportion of amylose in the starch of less than 30% (w/w). For example, the use of bread comprising the altered wheat starch would improve the bowel health and/or metabolic health indice relative to when the same quantity of bread is used, made with wild-type wheat starch.

The invention includes a change of at least 1%, at least 2%, at least 5%, at least 10%, at least 15%, at least 20%, at least 25%, at least 30%, at least 35%, at least 40%, at least 45% or at least 50% in any one or more of the bowel health or metabolic health indicators or both.

The method may be particularly beneficial in treating a human having any one or more of the conditions: constipation, diarrhea, irritable bowel syndrome, Crohn's disease, colorectal cancer, diverticular disease, ulcerative colitis, high blood LDL cholesterol, uremia resulting from kidney disease or other diseases, or diabetes. The method may be used to reduce blood cholesterol levels, in particular blood low density lipoprotein (LDL) levels, or as a method to reduce or control the weight of the animal, particularly a human. Alternatively, the method provides for the prevention or reduced risk in a human of any one or more of these conditions.

The decrease in the bowel contents is preferably at least 0.1 pH units, but may be at least 0.2, at least 0.3, at least 0.4 or at least 0.5 pH units. The change in pH may be measured in faeces, or internally, for example in the caecum, in the proximal colon or the distal colon.

The Short Chain Fatty Acids (SCFA), the concentration or total amount of which may vary, can be any one or more of formates, acetate, propionate, butyrate, succinate or branched forms thereof. Preferably the SCFA is one or more of acetate, propionate or butyrate, and most preferably is butyrate. Alternatively the change in concentration or total amount is a pooled value of total SCFA or a selected group of one or more of them. The concentration change may be as measured in faeces, or internally, which may be in the caecum, the proximal colon, the distal colon or any combination of these. The total amount may increase while the concentration remains the same or even increases if the bowel contents increase in volume over time. The SCFA content is thus a measure of the total amount of one or more SCFA in either the caecum, proximal colon, or distal colon or two or more of these combined. The concentrations or amounts might exhibit an increase of at least 5%, at least 10%, at least 15%, at least 20% or at least 50%.

Fecal bulk increases principally as a result of greater numbers of bacteria that are supported in the caecum and colon. The volumes may be measured by an increase in quantity of feces, or may be measured in situ by estimating the volume of cecal, proximal colon, or distal colon contents, separately or as a combination of two of these or all three of these. The increase in volume might be at least 5%, at least 10%, at least 15%, at least 20% or at least 50%.

The water volume of the bowel or faeces increases as a result principally of increased number of bacteria. The water content can be measured by comparing the wet weight of the faeces or bowel contents with dry weight after drying, the volume of water can be calculated from this decrease in weight. This increase in water volume might be in cecal, proximal colon, or distal colon contents, separately or as a combination or two of these or all three of these. The increase in volume might be at least 5%, at least 10%, at least 15%, at least 20% or at least 50%

Laxation relates to the passage of solids from the bowel, and entails measuring defecation in a quantitative and/or qualitative manner. Frequency of defecation is one aspect of Taxation and thus the frequency of defecation might increase at least 20%, at least 30%, at least 50%, or at least 100%. One qualitative measure relates to hardness of stools, whereby passage is easier, in contrast to constipation, but where stools are not so soft or loose as to constitute diarrhea. This measure might be considered related to the water volume of the feces and these may increase by 5%, at least 10%, at least 15%, at least 20% or at least 50%.

The probiotic bacteria are generally considered those that might be good for bowel health, being non infectious and producing beneficial metabolites as a result of their fermentation activities. Among the probiotic bacteria, bifidobacterial species are the most prominent. Lactic acid bacteria are similarly included such as, for example, Lactohacillus bulgaricus, Lactobacillus acidophilus, Lactobacillus casei, Lactobacillus plantarum, Streptococcus faecium or Streptococcus thermophilus. Numbers of individual species or genera might individually or collective increase by at least 20%, at least 25% or at least 50%. There may also be a reduction in the number of bacterial species that have a potentially adverse effect on the large bowel. Many such species are unable or less able to utilise resistant starch for energy compared to the probiotic organisms. Examples of such adverse bacteria include some Clostridia, Veillonella and Klebsiella.

Preferably the resistant starch enhances fecal bile acid excretion. Increased fecal bile acid excretion induces the liver to produce more bile acids, utilizing cholesterol as a substrate in the production of the bile acids. The liver can obtain cholesterol for the synthesis of bile acids from the blood, lowering blood cholesterol concentrations. Alternatively this may simply be used as a general marker of bowel activity, and clearance of bile. The build up of bile acids is also thought to have at least a correlation to bowel pathogensis. The increase might be by at least 5%, at least 10%, at least 15%, at least 20% or at least 50%. Similar decreases of plasma LDL cholesterol levels may also be exhibited.

Preferably the resistant starch also reduces urinary and fecal levels of putrefactive products or indicators of putrefactive products. This is indicative of a reduced level of fermentation by putrefying bacteria in the colon or caecum. Additionally these may be indicative of reduced small intestinal overgrowth. The level of these compounds can measured for, by example, using HPLC or other techniques. Many of these compounds are metabolic products or biproducts of protein or amino acid degradation. Compounds may be urea, ammonia and other waste nitrogen products or sulfides and sulfur containing compounds including hydrogen sulfide gas. Specific compounds that may be tested include but are not limited to phenol, indole, skatole, and ammonia, p-cresol, 4-ethylphenol, urea, ketones, and amines. The decrease may be by at least 5%, at least 10%, at least 15%, at least 20% or at least 50%.

The reduction of inflammation of the bowel might be by at least 10%, at least 20% or at least 50%

In kidney failure there is a decrease in the glomerular filtration rate and the kidneys are unable to maintain homeostasis of the blood. Homeostatic balance of water, sodium, potassium, calcium and other salts is no longer possible and nitrogenous wastes are not excreted. Retention of water causes edema and as the concentration of hydrogen ions increases, acidosis develops. Nitrogenous wastes accumulate and a condition referred to as uremia develops in the blood and tissue. Examples of uremic toxins include, but are not limited to, ammonia, urea, creatinine, phenols, indoles, and middle molecular weight molecules. There may also be an accumulation of phosphate.

Reduced kidney function is to some extent compensated for by the intestinal wall which also acts as a semipermeable membrane allowing small molecules to pass from the intestinal tract into the bloodstream and preventing larger molecules from entering the circulation. Nitrogenous wastes such as urea, creatinine and uric acid, along with several other small and medium molecular weight compounds, flow into the intestine and equilibrate across the intestinal epithelium. The present invention enhances the capacity of the bowel and thus enhances removal of waste products across the bowel. This enhancement of bowel function thus has a second very important function in uremic patients over and above benefits that are provided for normal individuals. The capacity of enhanced function can be measured by reduced levels of waste compounds in urine associated with uremic patients such as, for example, urea, creatinine and phosphate. These may be reduced in level by at least 5%, at least 10%, at least 15%, at least 20% or at least 50%. Plasma levels of these compounds, reduced to the same extent, may also be exhibited in preferred embodiments of the invention in uremic patients.

After ingestion of food there is generally an initial excursion in blood sugar levels, the rate of increase depending on the food ingested. Over a period of 1-2 hours in normal individuals, the blood sugar level is brought down to a generally elevated level through production and function of insulin. However, it is desirable to have a lower rate of increase and lower peak level in the blood sugar, with the increase prolonged over an extended period, not only in normal individuals but even more so in individuals with diabetes or Insulin deficiency (ID). A prolonged absorption of carbohydate from the bowel is also desirable, particularly in sufferers of diabetes, to counter the hypoglycaemia that is often encountered, particularly at night time. Because it is relatively resistant to digestion, the modified starch or wheat product of the present invention enhances glycemic control in healthy individuals and particularly in the diabetic patient. An advantage of the present invention is therefore that it provides a composition having effectively low carbohydrate content and starch that is more slowly digested.

Slower glucose absorption slows insulin release and reduces excessive insulin responses in response to rising blood glucose levels after a meal. This benefits pancreatic secretion of insulin by reducing both the glucose load and rate of glucose load over the initial phases of glucose detection, absorption and metabolism by the body. Reduced rates of glucose loading therefore reduces the stress on beta cells normally associated with the insulin response to rising glucose. Moreover, slower or moderated glucose absorption permits more time for insulin to stimulate normal sugar metabolic routes. Consequently, insulin dependent mechanisms have more time to prepare for the arrival of sugars from the intestine. This moderation of glucose absorption improves short-term insulin modulation in the liver, muscle, and adipose tissue.

Blood glucose measurements may be made by any number of methods. The timing of any blood glucose test may be material, and the present invention contemplates determining the fasting blood glucose level and especially the post-prandial blood glucose level. In general, the desirable fasting glucose level (pre-prandial) is 80 to 120 mg/dL, and a non-diabetic has a pre-prandial glucose level of less than 110 mg/dL. The desirable post-prandial level is 100 to 140 mg/dL, and a non-diabetic has a bedtime glucose level of less than 120 mg/dL. Under the American Diabetes Clinical Practice Recommendations, additional action is recommended if the fasting blood glucose level is greater than 140 mg/dL or the post-prandial glucose level is greater than 160 mg/dL.

In a preferred form, the post prandial glucose level after ingestion of food according to the present invention is less than about 160 mg/dL, more preferably less than about 155, 150, 145, 140, or 130 mg/dL.

The blood glucose response (peak level) resulting when the modified wheat or starch of this invention is utilized is preferably no more than 50%, more preferably no more than 12% compared to when glucose or dextrose is used, while the blood glucose response (area under the concentration/time curve) is no more than 75%, preferably no more than 30%, even more preferably, no more than 10% of the blood glucose response resulting when dextrose or glucose is used. The blood glucose response (peak) is defined as the rise in blood glucose concentration from the pre-feeding concentration to the peak concentration (usually occurring within one hour after feeding), expressed as a percentage of the rise observed when an equivalent mass of glucose or dextrose is fed.

Similarly post prandial plasma insulin levels may be reduced by at least 5%, at least 10%, at least 15%, at least 20% or at least 50% compared to when unmodified wheat or starch is used.

The profile of lipids in the blood may be reflective of disorders of lipid synthesis and transport in the individual. Abnormal patterns of blood lipid profile, also known a dyslipidemias, may be characterized by one or more of the following: elevated levels of total and low density lipoprotein (LDL)-cholesterol, elevated levels of triglycerides (TG), low levels of high density lipoprotein (HDL)-cholesterol, a high LDL/HDL ratio, or elevated levels of FFA (free fatty acids). An imbalance of lipids may also be exhibited in individuals that suffer from diabetes or have syndrome X. Generally it is desired to reduce total plasma cholesterol (C), LDL-C and very low density lipoprotein triglycerides (VLDL-triglycerides) and TG, elevated levels of which are associated with health risks, while raising serum levels of HDL-C which is considered a “healthy” lipoprotein. The invention in a preferred form exhibits a variation of blood levels of these by at least 5%, at least 10%, at least 15%, at least 20% or at least 25%.

Whilst the invention may be particularly useful in the treatment or prophylaxis of humans, it is to be understood that the invention is also applicable to non-human animals including but not limited to agricultural animals such as cows, sheep, pigs and the like, domestic animals such as dogs or cats, laboratory animals such as rabbits or rodents such as mice, rats, hamsters, or animals that might be used for sport such as horses. The method may be particularly applicable to non-ruminant mammals or animals such as mono-gastric mammals. The invention may also be applicable to other agricultural animals for example poultry including, for example, chicken, geese, ducks, turkeys, quails, or fish.

The method of treating the animal, particularly humans, may comprise the step of administering altered wheat grain, flour or starch to the animal, in one or more doses, in an amount and for a period of time whereby the level of the one or more of the bowel health or metabolic indicators improves. The indicator may change relative to consumption of non-altered wheat starch or wheat or product thereof, within a time period of hours, as in the case of some of the indicators such as pH, elevation of levels of SCFA, post-prandial glucose fluctuation, or it may take days such as in the case of increase in fecal bulk or improved Taxation, or perhaps longer in the order of weeks or months such as in the case where the butyrate enhanced proliferation of normal colonocytes is measured. It may be desirable that administration of the altered starch or wheat or wheat product be lifelong. However, there are good prospects for compliance by the individual being treated given the relative ease with which the altered starch can be administered.

Dosages may vary depending on the condition being treated or prevented but are envisaged for humans as being at least 1 g of altered starch per day, more preferably at least 2 g per day, preferably at least 10 or at least 20 g per day. Administration of greater than about 100 grams per day may require considerable volumes of delivery and reduce compliance. Most preferably the dosage for a human is between 5 and 60 g of altered starch per day, or for adults between 5 and 100 g per day.

The altered wheat starch of the present invention is able to be readily incorporated into food or beverage products at levels typically ingested in normal human diets. Intake of at least about 10 g per day is thought to provide a measurable benefit, although more preferably the intakes are at least about 20-30 grams of the altered wheat starch per day. Typically, humans have daily intakes of at least 100 to 200 g of starchy food products such as bread or pasta, which means that levels of altered starch in the food product of at least 5 to 10% will typically provide a beneficial effect. It is proposed that levels of less than that, for example, as low as 1% will also give a beneficial effect which may or may not be immediately measurable.

Thus a second aspect of the invention provides a food, beverage or pharmaceutical preparation comprising at least 1% (w/w) altered wheat starch in the form of or derived from the grain of a wheat plant, wherein the proportion of amylose in the starch of the grain is at least 30%. In a preferred embodiment, said grain comprises a reduced level of enzyme activity and/or protein of starch synthase IIa enzyme or a starch branching enzyme in the endosperm. The starch branching enzyme may be SBEIIa or both SBEIIa and SBEIIb. It will be understood that the levels are reduced relative to wild-type grain. In an embodiment, the grain comprises one or more genetic variations which lead to a reduction in the level of the starch synthase and/or starch branching enzyme gene expression, starch synthase and/or starch branching enzyme activity in the endosperm or both relative to wild-type grain, which genetic variation comprises a mutation of a starch synthase and/or starch branching enzyme gene or an introduced nucleic acid which encodes an inhibitor of starch synthase and/or starch branching enzyme gene expression. In a further embodiment, the grain comprises one or more genetic variations which lead to a reduced level of enzyme activity and/or protein in the endosperm of SSIIa, SBEIIa, or SBEIIa and SBEIIb relative to wild-type grain, which genetic variations comprise one or more mutations in genes encoding SSIIa, SBEIIa, or SBEIIa and SBEIIb, respectively, and/or one or more introduced nucleic acids which encode inhibitors of expression of genes encoding SSIIa, SBEIIa, or SBEIIa and SBEIIb.

In an embodiment, the altered wheat starch comprises at least 2% (w/w) resistant starch, preferably at least 3%, at least 4%, at least 5%, at least 6% or at least 10% resistant starch, but the level may be higher perhaps at least 20%, 30%, 40% or 50%. In another embodiment, the proportion of amylose in the altered wheat starch derived from the grain is at least 30% (w/w), preferably at least 35%, at least 40%, at least 45%, at least 50%, at least 65%, at least 70%, at least 75% or at least 80%.

The food, beverage or pharmaceutical preparation may comprise at least 1% (w/w) resistant wheat starch derived from the grain of a wheat plant wherein the proportion of amylose in the starch of the grain is at least 50%.

The proportion of amylose in the starch of the grain may be at least 30% and more preferably at least about 35%, at least 40%, at least 45%, at least 50% or at least 55%. The wheat plant may additionally comprise a reduced level of SBEI protein, enzyme activity or both relative to wild-type grain. The wheat plant may additionally comprise an altered level of one or more enzymes relative to wild-type grain, wherein said enzyme may be ADP glucose pyrophosphorylase, GBSS, SSI, SSIII, phosphorylase, a debranching enzyme of an isoamylase type, or a debranching enzyme of a pullulanase type. The altered level may be an increased level or a decreased level.

The amylopectin of the grain may have a reduced proportion of the 4-12 dp chain length fraction relative to the amylopectin of wild-type grain, as measured after isoamylase debranching of the amylopectin.

The food or beverage product may have at least 2% (w/w), preferably at least 3%, at least 4%, at least 5%, at least 6%, at least 8%, at least 10%, at least 15%, at least 20%, at least 25%, at least 30%, at least 35%, at least 40% or at least 50% altered or resistant wheat starch.

It is thought that heating or baking of the food product is preferred because this results in increased retrogradation of the starch on cooling and therefore may enhance the level of resistant starch. In an embodiment, the starch in the form of grain, flour, wholemeal or other form, or the food, beverage or pharmaceutical preparation containing the starch is heated to at least 60° C. for at least ten minutes one or more times, which may be prior to or during preparation of the food, beverage or pharmaceutical preparation, with subsequent cooling, to provide greater disruption of the starch granules and greater crystallization. The starch, food or beverage product is preferably heated to higher temperatures, preferably at least about 70° C., at least 80° C., at least 90° C., at least 95° C. or at least 100° C., perhaps also in the presence of elevated pressures.

The altered starch may be directly eaten as a powder or as an edible composition comprising resistant starch and water, resistant starch and food material, resistant starch in foods, resistant starch in beverages or resistant starch and seasonings. The altered starch may be incorporated into fat or oil products such as margarine or shortening, salad dressing, egg products such as mayonnaise, dairy products such as milk, yogurt or cheese, cereal products such as corn or wheat flour, fruit juices, other foods or food materials, or the altered starch may be processed into beverages or foods such as bread, cake, biscuits, breakfast cereals, pasta, noodles or sauces. Other products include prepacked mixes such as, for example, pancake or cake mixes. Alternatively, the altered wheat starch may be provided as a pharmaceutical preparation preferably for orally administration such as, for example, tablets, capsules, granules, powders, syrups or suspensions. Alternatively, these may be parenterally administered.

When incorporated into bread or other foods, the altered wheat starch may be in the form of grain, flour, wholemeal or purified starch. It may be used as a partial replacement for non-altered wheat forms and may replace at least 5% (w/w), at least 10%, at least 15%, at least 20%, at least 25%, at least 30%, at least 35%, at least 40%, at least 45%, at least 50% or more of the non-altered form using in conventional formulations. For breads, the replacement is preferably in the range of 10% to 100% or 50% to 100%. This may assist to minimise the impact on the baking process while providing for an adequate delivery of modified wheat starch on ingestion of a typical daily intake of 100 to 200 grams. Alternatively the flour incorporated into the bread may be derived solely from the modified wheat.

The food or beverage or pharmaceutical preparation may be packaged ready for sale or in bulk form.

The invention also provides methods of preparing the food, beverage or pharmaceutical preparation of the invention, and recipes or instructions for preparing such foods or beverages. The methods or recipes or instructions may include the step of heating or baking the altered starch ingredient or the product to at least 60° C. for at least ten minutes one or more times, or preferably to at least 100° C., at least 120° C., at least 140° C., at least 180° C., at least 200° C. or at least 220° C. The method may include the step of packaging the product so that it is ready for sale.

The invention also provides for the use of the food, beverage or pharmaceutical preparation in the treatment, prevention or reduced risk of any of the conditions: constipation, diarrhea, irritable bowel syndrome, Crohn's disease, colorectal cancer, diverticular disease, ulcerative colitis, high blood LDL cholesterol, uremia resulting from kidney disease or other diseases, diabetes, reducing blood cholesterol levels, in particular blood low density lipoprotein (LDL) levels, or to reduce or control the weight of the animal, particularly a human. The invention also provides for the preparation of medicaments for use in treating or preventing such conditions.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1. Sequence of the Starch Branching Enzyme IIa gene (wSBE II-D1) [SEQ ID No. 1] from A. tauschii, corresponding to the D genome SBEIIa gene of hexaploid wheat (T. aestivum) FIGS. 1A-D are partial views of FIG. 1, that begin with FIG. 1A and continue to FIG. 1D respectively.

FIG. 2. Partial wheat SBEIIb gene sequence (wbe2b genomic) [SEQ ID No. 2] from T. aestivum. FIG. 2A-B are partial views of FIG. 2, that begin with FIG. 2A and continue to FIG. 2B.

FIG. 3. Schematic of duplex-RNA constructs. A. The order of the gene elements used were promoter, SBEIIa or SBEIIb gene sequence (exons 1, 2 and 3) in sense orientation, intron (intron 3), SBEIIa or SBEIIb gene sequence (exons 1, 2, 3 and 4) in antisense orientation, and transcription terminator/polyadenylation sequence. Transcription in the transgenic wheat occurs in the orientation from promoter to terminator. B. The transcript of the ds-SBEIIa or ds-SBEIIb gene in transformed plants forms a “hairpin” RNA structure with a double-stranded region formed by hybridization between the sense and sequence and its complement (antisense sequence). The intron sequence bordered by the GT and AG nucleotides is spliced out after transcription.

FIG. 4. Water absorption parameters for blends of high amylose flour from transgenic (T) and control (C) varieties, mixed in the ratios 0:100 (Control), 10:90 (10T90C), 20:80 (20T80C), 30:70 (30T70C), 50:50 (50T50C), 75:25 (75T25C), 100:0 (Pure T), as measured by Micro Z-arm mixing. Transgenic varieties used were 50.3x/6/(60.1% amylose) and 85.2c (81% amylose).

FIG. 5. Specific volume for admixtures of high amylose and control flours, mixed in ratios as indicated. Transgenic varieties and X-axis labels are as for FIG. 4.

FIG. 6. Mixing time of doughs made from mixtures of high amylose (T) and control (C) wheat flour as determined by Mixograph mixing. Transgenic varieties and X-axis labels are as for FIG. 4.

FIG. 7. In vitro Glycemic Index (GI) and Resistant Starch (RS) data for breads made from modified wheats, from doubled-haploid progeny of a cross between varieties Sunco and an SSIIa triple null mutant, or high amylose lines (transgenic lines 50.3x and 85.2c). Lanes correspond to samples with the following SSIIa or SBEIIa genotypes: Lane 1, ABd; 2, aBd; 3, aBD; 4, ABd; 5, aBD; 6, ABD (“wildtype”); 7, aBD; 8, AbD; 9, Abd; 10, abD; 11, abD; 12, AbD; 13, ABD; 14, aBd; 15, AbD; 16, aBd; 17, Abd; 18, ABD; 19, abd; 20, abD; 21, abd; 22, SGP-1 control; 23, abd; 24, abd; 25, Wonderwhite bread control; 26, high amylose transgenic line 50.3x; 27, high amylose transgenic line 85.2c. Lower case letters a, b and d represent the presence of the mutant alleles for SSIIa on the A, B and D genomes of wheat, respectively. Therefore “abd” represents the triple null allele. “Wonderwhite” represents bread made with added high amylose maize starch (approximately 10%, TipTop bakeries, Australia).

FIG. 8. In vitro GI and RS data for breads made with blended high amylose flour: control flour. Samples to the right of the vertical arrow, containing at least 30% transgenic high-amylose flour, had an RS level of at least 2%.

FIG. 9. Nucleotide sequence of a cDNA encoding wheat SBEIIb [SEQ ID NO. 3]. FIG. 9A-C are partial views of FIG. 9, that begin with FIG. 9A and continue to FIG. 9C respectively.

FIG. 10. Lineup of wheat SSIIa cDNA nucleotide sequences. wSSIIA (A genome sequence) corresponds to Accession No. AF155217, Li et al., 1999) [SEQ ID No. 12]. The other sequences, wSSIIB [SEQ ID NO. 13] and reverse transcript of wSSIIB mRNA [SEQ ID NO 14] are from WO00/66745. The protein coding region corresponds to nucleotide positions 176-2572.

FIG. 10A-F are partial views of FIG. 10, that begin with FIG. 10A and continue to FIG. 10F respectively.

FIG. 11. Schematic of the three mutant SSIIa alleles in the triple-null SGP-1 line. Exons are shown as thick bars, introns as thin bars. Deletions and insertions are shown as hatched regions.

FIG. 12. Agarose gel electrophoretogram of PCR products amplified from Sunco (wildtype), the triple null SGP-1 mutant, and nullisomic-tetrasomic lines in a Chinese Spring background which were nullisomic for chromosome 7A (N7A), 7B (N7B) or 7D (N7D). Primer pairs were as described in the text.

FIG. 13. RVA pasting results of SSIIa samples. Panel A: Typical RVA profiles of wild type, single null, double null and triple null samples. Panel B: Average RVA peak viscosity results for 40 lines representing the eight genotypes for SSIIa.

FIG. 14. Typical DSC gelatinisation endotherms for starch obtained from grain of different SSIIa genotypes.

FIG. 15. Specific volume (mL/g) of breads made from flour from different SSIIa genotypes.

FIG. 16. Comparison of wheat SBEIIa and SBEIIb sequences using GAP. FIG. 16A-E are partial views of FIG. 16, that begin with FIG. 16A and continue to FIG. 16E respectively.

DETAILED DESCRIPTION OF THE INVENTION

The invention is based on the finding that the production of modified wheat and its incorporation into the diet of animals, particularly mammals, results in the improvement of bowel health as measured by several indicators. Furthermore, food products made with the modified wheat showed attributes such as increased levels of resistant starch (RS) and lower glycemic index (GI) and therefore consumption of the food products also provides improved metabolic health. The wheat plant is modified in starch biosynthesis, in particular to elevate the proportion of amylose in the starch of the grain.

A wheat plant is defined herein as any plant of a species of the genus Triticum, which species is commercially cultivated, including, for example, Triticum aestivum L. ssp. aestivum (common or bread wheat), other subspecies of Triticum aestivum, Triticum turgidum L. ssp. durum (durum wheat, also known as macaroni or hard wheat), Triticum monococcum L. ssp. monococcum (cultivated einkorn or small spelt), Triticum timopheevi ssp. timopheevi, Triticuin turgigum L. ssp. dicoccon (cultivated emmer), and other subspecies of Triticum turgidum (Feldman). The wheat may be hexaploid wheat having an AABBDD type genome, or tetraploid wheat having an AABB type genome. Since genetic variation in wheat according to the invention can be transferred to certain related species including rye and barley by hybridization, the invention also includes use of the hybrid species thus formed, including triticale that is a hybrid between bread wheat and rye. In a particular embodiment, the wheat plant is of the species Triticum aestivum, and preferably of the subspecies aestivum. Alternatively, since mutations or transgenes can be readily transferred from Triticum aestivum to durum wheat, in another embodiment the wheat is Triticum turgidum L. ssp. durum.

The wheat plant is modified according to the invention so that it produces altered starch in its grain. “Starch” is defined herein as polysaccharide made up essentially of α-glucopyranose units. Starch is the major storage carbohydrate in wheat, is synthesized in the amyloplasts and formed and stored in granules in the developing grain. It includes amylose, an essentially linear (<0.1% branchpoints) α-1,4-D-glucopyranose polymer and amylopectin, which has short chains of α-D-glucopyranose units primarily linked by α-1,4 bonds with α-1,6 linked branches. Wheat starch from wild-type plants comprises up to about 20%-30% of amylose and about 70%-80% of amylopectin. A further significant difference between amylose and amylopectin is in the molecular weight of the polymers. Amylose has a helical conformation with a molecular weight of 10⁴-10⁶ daltons while amylopectin has a molecular weight of about 10⁷ to 10⁸ daltons. Recent studies have shown that up to about 0.1% of α-1,6-glycosidic branching sites may occur in amylose, therefore it is described as “essentially linear”. “Amylose” is defined herein as including essentially linear molecules of α-1,4 linked glucosidic (glucopyranose) units and amylose-like long-chain amylopectin (sometimes referred to as “intermediate material” or “amylose-like amylopectin”, Takeda et al., 1993b; Fergason, 1994). The proportion of amylose in the starch as defined herein is on a weight/weight (w/w) basis, i.e. the weight of amylose as a percentage of the weight of total starch from the grain. Amylose content may be determined by any of the methods known in the art including size exclusion HPLC, for example in 90% (w/v) DMSO, concanavalin A methods (Megazyme Int, Ireland), or preferably by iodometric methods, for example as described in Example 1. The HPLC method may involve debranching of the starch (Batey and Curtin, 1996) or not involve debranching. From the grain weight and amylose content, the amount of amylose deposited per grain can be calculated and compared for modified and control lines.

The modification of the wheat plant according to the invention includes one or more alterations in the activity or amount of starch biosynthetic enzymes in the endosperm. “Endosperm” as used herein has the normal meaning known in the art, being the tissue that is the primary site of starch synthesis and deposition in the developing grain, and the primary product of milling of mature grain to remove the aleurone and germ. In one embodiment, the alteration comprises a reduction in the amount and/or activity of a starch synthase enzyme or a starch branching enzyme in the wheat endosperm, which results in an increased proportion of amylose in the starch of the mature wheat grain. This may be represented as a reduction in the amount and/or activity of starch synthase IIa (SSIIa) or starch branching enzyme IIa (SBEIIa). In another embodiment, the modification comprises reduction in SBEIIb as well as SBEIIa activity. Mutation in the genes encoding these two activities in wheat is aided by the surprising finding that SBEIIa and SBEIIb are closely linked in wheat, in contrast to non-linkage in maize and rice. In a further embodiment, the modification comprises reduction in all three of SBEIIa, SBEIIb and SBEI. Other starch biosynthesis enzymes that may be altered in combination with any of the above include starch synthase I (SSI), starch synthase IIb (SSIIb), starch synthase III (SSIII), phosphorylase or starch debranching enzymes such as isoamylase or pullulanase. The alterations may be, for example, increased activity, decreased activity, altered localization or timing of activity. When alterations in some of these enzymes are combined, characteristics of the starch other than the relative amylose content may also be altered. In an embodiment, the modified wheat comprises alterations in the activity of multiple starch biosynthesis enzymes in wheat endosperm, preferably including a reduction in the activity of SBEIIa or SBEIIb or SSIIa such that the proportion of amylose in the starch of the grain is increased. In a further embodiment, the activity of one or more starch biosynthesis enzymes is altered in the plant in tissues other than endosperm, for example the activity of SBEI, SBEII or SSIIa may be increased in leaves to compensate for some loss of activity caused by a transgene encoding a corresponding inhibitory molecule intended primarily for expression in the endosperm. Starch synthesis may be further improved by the overexpression of one or more starch biosynthetic enzymes in combination with a reduction in SBEIIa, SBEIIb or SSIIa. Genes encoding such enzymes may be from any of a variety of sources, for example from bacterial or other sources other than wheat, and may be modified to alter the catalytic properties, for example alteration of the temperature dependence of the enzymes (for example, see WO94/0944).

The high amylose phenotype may be achieved by partial or full inhibition of the expression of SSIIa, SBEIIa or SBEIIa and SBEIIb genes. A “high amylose” phenotype or “high amylose level in the starch of the grain” or the like as used herein refers to total starch obtained from the grain having at least 30% amylose. The extent to which the gene or genes are inhibited will in some degree determine the characteristics of the starch made in the wheat grain. Any of a range of gel electrophoresis techniques carried out on the proteins extracted from the modified wheat endosperm will reveal the nature and extent of modification to the starch synthase enzyme or starch branching enzyme activity. Modification may occur as a reduction in enzyme activity, complete abolition of enzyme activity, or an alteration in the distribution of the enzyme or enzymes within the endosperm. For example, SSIIa, SBEIIa, SBEIIb or other activity may be reduced by affecting the distribution of the enzymes within the endosperm, such as reducing the level of enzyme that is starch granule-bound. To carry out these tests, starch may be extracted from the wheat endosperm and the proteins therein analyzed, for example as outlined in Rahman et al, 1995. Techniques well known in the art such as SDS-PAGE and immunoblotting are carried out on the soluble and the starch granule fractions and the results used to identify the plants or grain where modifications have occurred to the starch synthase or starch branching or other enzymes.

Alteration of the starch biosynthesis enzyme activities may be achieved by the introduction of one or more genetic variations into the wheat plant. That is, the genetic variations lead, directly or indirectly, to the alteration in enzyme activity in the endosperm during grain development and consequently to the starch modifications described herein. A reduction in the level of SSIIa, SBEIIa, SBEIIb or other enzyme activity may be accomplished by a reduction in the expression of one or more genes encoding the enzymes, which may be achieved by mutation, a combination of mutations, or the introduction of one or more nucleic acids, for example a transgene which encodes an inhibitory molecule. Examples of inhibitory molecules include antisense, co-suppression, ribozyme or duplex RNA molecules.

As used herein, the terms “altering”, “increasing”, “increased”, “reducing”, “reduced”, “inhibited” or the like are considered relative terms, i.e. in comparison with the wild-type or unaltered state. The “level of a protein” refers to the amount of a particular protein, for example SBEIIa, which may be measured by any means known in the art such as, for example, Western blot analysis or other immunological means. The “level of an enzyme activity” refers to the amount of a particular enzyme measured in an enzyme assay. It would be appreciated that the level of activity of an enzyme might be altered in a mutant if a more or less active protein is produced, but not the expression level (amount) of the protein itself. Conversely, the amount of protein might be altered but the activity (per unit protein) remain the same. Reductions in both amount and activity are also possible such as, for example, when the expression of a gene encoding the enzyme is reduced transcriptionally or post-transcriptionally. In certain embodiments, the reduction in the level of protein or activity is by at least 40% or by at least 60% compared to the level of protein or activity in the endosperm of unmodified wheat, or by at least 75%, at least 90% or at least 95%. The reduction in the level of the protein or enzyme activity or gene expression may occur at any stage in the development of the grain, particularly during the grain filling stage while starch is being synthesized in the developing endosperm, or at all stages of grain development through to maturity. In a further embodiment, the level of SBEIIa or other enzyme is reduced in the endosperm by at least 50% compared to the wild-type. The term “wild-type” as used herein has its normal meaning in the field of genetics and includes wheat cultivars or genotypes which are not modified as taught herein.

The amount or the activity of enzymes such as SSIIa, SBEIIa, SBEIIb in wheat endosperm may be measured using any method known in the art such as, for example, by immunodetection methods, Western blotting or ELISA assays, or the level of its corresponding mRNA may measured by methods such as Northern blot hybridization analysis or reverse transcription polymerase chain reaction (RT-PCR). A wheat plant or grain having an altered level of a particular protein or enzyme activity in its endosperm may be screened or selected based on a reduced level of the protein or enzyme (direct assay), or it may be based on the phenotype of the grain of the wheat plant such as an increased proportion of amylose or decreased proportion of amylopectin, or a visual phenotype, for example shrunken grain or altered starch granule properties. The wheat plant with the altered starch properties as used herein may be identified using any of the methods known in the art, either directly determining the starch properties or indirectly, for example, detecting the presence of a genetic variation in the plant or its grain. The plant may be a plant in a population of wheat plants, such as, for example, in wheat breeding.

The “wheat SBEIIa gene” or the like as used herein refers to a nucleotide sequence encoding starch branching enzyme IIa in wheat, which can readily be distinguished from SBEIIb or other proteins by those skilled in the art. This includes the naturally occurring variants of the genes existing in wheat, including those encoded by the A, B and D genomes of breadwheat, as well as non-naturally occurring variants which may be produced by those skilled in the art of gene modification. Examples are shown in Table 1. In a preferred embodiment, a wheat SBEIIa gene refers to a nucleic acid molecule, which may be present in or isolated from wheat or derived therefrom, comprising nucleotides having a sequence having at least 80% identity to the coding region of the wSBEIIa-D1 gene shown in SEQ ID NO: 1. In analogous fashion, a “wheat SBEIIb gene” as used herein refers to a nucleotide sequence encoding starch branching enzyme IIb in wheat. A partial wheat SBEIIB gene sequence (wbe2b genomic) from T. aestivum is shown in FIG. 2 (SEQ ID NO: 2). A wheat SBEIIb cDNA sequence is shown in FIG. 9. A comparison of wheat SBEIIa and SBEIIb cDNA sequences using the program GAP is shown in FIG. 16, showing that the two nucleotide sequences are about 73.3% identical over the full length.

In analogous fashion, the “wheat SSIIa gene” or the like as used herein refers to a nucleotide sequence encoding starch synthase IIa in wheat, which can readily be distinguished from other starch synthases or other proteins by those skilled in the art. This includes the naturally occurring variants of the genes existing in wheat, including those encoded by the A, B and D genomes of breadwheat, as well as non-naturally occurring variants which may be produced by those skilled in the art of gene modification. Examples are reported in WO00/66745. In a preferred embodiment, a wheat SSIIa gene refers to a nucleic acid molecule, which may be present in or isolated from wheat or derived therefrom, comprising nucleotides having a sequence having at least 80% identity to the coding region of the wSSIIa gene shown in WO00/66745.

SBE activity may be measured directly by enzyme assay, for example by the phosphorylase stimulation assay (Boyer and Preiss, 1978). This assay measures the stimulation by SBE of the incorporation of glucose 1-phosphate into methanol-insoluble polymer (α-D-glucan) by phosphorylase a. SBE activity can be measured by the iodine stain assay, which measures the decrease in the absorbance of a glucan-polyiodine complex resulting from branching of glucan polymers. SBE activity can also be assayed by the branch linkage assay which measures the generation of reducing ends from reduced amylose as substrate, following isoamylase digestion (Takeda et al., 1993a). Preferably, the activity is measured in the absence of SBEI or SBEIIb activity. Isoforms of SBE show different substrate specificities, for example SBEI exhibits higher activity in branching amylose, while SBEIIa and SBEIIb show higher rates of branching with an amylopectin substrate. The isoforms may also be distinguished on the basis of the length of the glucan chain that is transferred. SBE protein may also be measured by using specific antibodies such as those described herein. The SBEII activity may be measured during grain development in the developing endosperm, or alternatively in the mature grain where the protein is still present in equivalent, but unaltered, grain and can be assayed by immunological methods. Starch synthase activity may be measured by extraction of proteins from endosperm and assay as described in Example 1.

In one embodiment the modified wheat having altered starch has an increased proportion of amylose in the grain starch to at least 30%. Ordinarily in hexaploid and durum wheats, the proportion of amylose in starch is in the range from about 18 to about 30% (w/w). In this embodiment, the modified wheat comprises one or more genetic variations which result in the starch in its grain comprising at least 30% amylose. The proportion of amylose in the starch as defined herein is on a weight/weight (w/w) basis, i.e. the weight of amylose as a percentage of the weight of total starch from the grain. In further embodiments, the proportion of amylose in the starch is at least 40%, at least 45%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70% or at least 75% (each w/w). In further embodiments of the invention, the method provides for a proportion of amylose of at least 80% or at least 90% (w/w).

The wheat plants described herein for use in the invention include progeny plants which have the desired characteristics of the parental wheat plants, in genotype and/or phenotype, into which the modifications were introduced. The wheat plants also encompass the genetic variations(s) or mutations in other genetic backgrounds or other species which can be hybridised with the wheat plant as described above. The modified parental plants may be crossed with plants containing a more desirable genetic background. After the initial crossing, a suitable number of backcrosses may be carried out to remove the less desirable background. The desired genetic background may include a suitable combination of genes providing commercial yield and other characteristics such as agronomic performance or abiotic stress resistance. The genetic background might also include other altered starch biosynthesis or modification genes, for example genes from other wheat lines that have a shrunken endosperm where the causal gene is not known. The desired genetic background of the wheat may include considerations of agronomic yield and other characteristics. Such characteristics might include whether it is desired to have a winter or spring type of wheat, agronomic performance, disease resistance and abiotic stress resistance. In Australia one might want to cross the altered starch trait into wheat cultivars such as Baxter, Kennedy, Janz, Frame, Rosella, Cadoux, Diamondbird or other commonly grown varieties. The examples provided are specific for an Australian production region, and other varieties will be suited for other growing regions. It is preferred that the wheat variety of the invention provide a yield not less than 80% of the corresponding wild-type variety in at least some growing regions, more preferably not less than 90% and even more preferably not less than 95%. The yield can readily be measured in controlled field trials.

In an embodiment, the modified wheat plant comprises a mutation wherein the SBEIIa gene is absent from the long arm of chromosome 2A (2AL) or wherein the SBEIIa gene on the long arm of chromosome 2A comprises a mutation which leads to reduced level of SBEIIa enzyme activity in the endosperm of said grain relative to wild-type grain. Despite an extensive screen of 2400 wheat accessions, the inventors did not find such plants that were naturally occurring, suggesting that selection for retention of the functional SBEIIa gene on 2AL might be happening in nature. However, such plants could be produced and identified after mutagenesis. These plants are non-transgenic which is desirable in some markets. These plants may be bread wheat, durum wheat or other wheat. In a preferred embodiment, the wheat plant comprises a deletion of at least part of the SBEIIa gene, which may extend to at least part of the SBEIIb gene, on the 2AL chromosome. As is understood in the art, hexaploid wheats such as bread wheat comprise three genomes which are commonly designated the A, B and D genomes, while tetraploid wheats such as durum wheat comprise two genomes commonly designated the A and B genomes. Each genome comprises 7 pairs of chromosomes which may be observed by cytological methods during meiosis and thus identified, as is well known in the art. Each chromosome has a centromere, which on chromosome 2 is positioned asymmetrically; therefore the two arms of chromosome 2 are designated “short” and “long”. The “long arm of chromosome 2A” is defined herein as the region of that chromosome 2A between the centromere and tip along the long arm, in accord with the standard meaning of the term. The terms “long arm of chromosome 2B” and the “long arm of chromosome 2D” are defined in the same way except that they relate to chromosome 2 of the B or D genomes of wheat, respectively.

We have found that the SBEIIa and SBEIIb genes are both present on chromosome 2 in wheat. In a particular embodiment, the wheat plant comprises the majority (>50%) of 2AL, which chromosome arm comprises a mutation of at least the SBEIIa gene. That is, chromosome 2AL is essentially present, comprising a mutation in at least the SBEIIa gene of the A genome. The presence of 2AL may be determined by cytological techniques such as, for example, in situ hybridization techniques or by using 2AL specific molecular markers. In a preferred embodiment, the wheat plant is homozygous for said mutation. The mutation may be a null mutation. The mutation may be a deletion.

The modified wheat plants and products obtained therefrom may be transgenic or non-transgenic. The invention also extends to the grain produced from the wheat plants and any propagating material of the wheat plants that can be used to produce the plants with the desired characteristics, such as cultured tissue or cells. The invention clearly extends to methods of producing or identifying such wheat plants or the grain produced by such plants.

The modified wheat plants as described herein, particularly the grain obtained from the plants or products containing the altered wheat starch obtained from the grain may be used in the production of a food, beverage or pharmaceutical preparation which is intended for consumption by, or administration to, an animal, preferably a mammal and in particular a human. The food, beverage or pharmaceutical preparation comprises the modified wheat grain or a product derived therefrom comprising the altered starch.

Modified Grain

The invention also provides foods, beverages or pharmaceutical preparations produced with modified wheat grain or altered starch obtained therefrom, obtained from wheat plants as described herein. Grain is defined herein as essentially mature grain. This includes grain as harvested in a commercial setting. In one embodiment, the altered starch is at least partly a consequence of reduced starch synthase enzyme or starch branching enzyme activity, more preferably SSIIa, SBEIIa or SBEIIa and SBEIIb activity, during development of the endosperm of the wheat grain. The grain may comprise an increased proportion of amylose as a percentage of total starch. This may be determined as a reduced proportion of amylopectin in the starch compared to grain from a wild-type plant. Wild-type wheat starch has approximately 18-30% amylose and 70-80% amylopectin. The grain for use in the invention comprises starch comprising at least 30% amylose, preferably comprising at least 50% (w/w) amylose. Increased amylose levels may be evidenced by abnormal starch granule morphology or loss of birefringence of the granules when observed under a light microscope or other methods known in the art. In a particular embodiment, the proportion of amylose in the starch of the grain is measured by an iodometric method, which may be a spectrophotometric method such as, for example, the method of Morrison and Laignelet (1983), or by high-performance liquid chromatography (HPLC, for example, Batey and Curtin, 1996).

The grain may be shrunken or non-shrunken, preferably having a non-shrunken phenotype. “Non-shrunken” as used herein is defined as where the majority of grains, preferably at least 90% of the individual grains, show a plump or fully-filled phenotype. This is usually associated with a normal or near normal level of starch accumulation. In contrast, a “shrunken” phenotype as used herein refers to the majority of grains, particularly at least 90% of the grains, having reduced starch accumulation. Slightly shrunken grain refers to a reduction in average starch content of at least 30%, moderately shrunken grain refers to a reduction in average starch content of at least 50%, and highly shrunken grain refers to a reduction in average starch content of at least 70%, each relative to wild-type grain. Shrunkenness may also be measured by the relative starch content, as a percentage of mature grain weight. Unaltered field-grown wheat grain has a starch content of about 65%, while in shrunken grain this is reduced to less than 50%.

In further embodiments, the grain has an average weight of at least 36 mg or 40 mg. The average weight of the grain is determined by measuring the weight of a known number of grains, being a representative sample of the batch of grain, and dividing the total weight by the number of grains. It would be appreciated that characteristics of the grain such as starch content, average weight and a non-shrunken phenotype that are near wild-type levels are desirable for commercial production of the grain. In further embodiments, the starch content of the grain is at least about 25%, 35%, 45%, or 55% to 65% (w/w). Wild-type wheat grown commercially usually has a starch content in the range 55-65%, depending somewhat on the cultivar grown. Alternatively, the grain of the invention has a starch content of at least 90% that of grain from an equivalent, but unaltered, wheat. Lower starch contents than wild-type are likely a consequence of reduced amylopectin levels. Even with lower starch contents, the grain may still be useful for commercial food production because of the relatively high value of the high amylose products. Other desirable characteristics include the capacity to mill the grain, in particular the grain hardness. Another aspect that might make a wheat plant of higher value is the degree of starch extraction from the grain, the higher extraction rates being more useful. Grain shape is also another feature that can impact on the commercial usefulness of a plant, thus grain shape can have an impact on the ease or otherwise with which the grain can be milled. For example, an elongated grain morphology may make it difficult to mill and process.

A fuller grain may be desirable in terms of achieving greater yields and certain benefits of the invention might be achieved, such as the production of starch with high levels of amylose, or in the alternative starch with altered chain length distributions. Thus the grain preferably has a non-shrunken phenotype. Other aspects of the invention may, however, be better achieved by a grain that is less filled. Thus the proportion of aleurone layer or germ or protein to starch may be higher in less filled grain, thereby providing for a wheat flour or other product that is higher in the beneficial constituents of the aleurone layer or protein. The high aleurone layer product might thus be higher in certain vitamins such as folate, or it might be higher in certain minerals such as calcium, and that combined with higher resistant starch levels might provide synergistic effects such as providing for enhanced uptake of minerals in the large bowel.

The invention also provides for the use of flour, meal, dough or other products produced from the grain or using the grain. These may be unprocessed or processed, for example by fractionation or bleaching. The invention further provides wheat grain useful for food production obtained from the wheat plant of the invention. Additionally the invention encompasses grain that has been processed in other ways, so that the grain may have been milled, ground, rolled, pearled, kibbled or cracked, or par boiled (polenta), for example as cous cous.

Altered Starch

In another aspect, the invention provides foods, beverages or pharmaceutical preparations produced with altered wheat starch obtained from the grain of the wheat plants as described herein, the starch having an increased proportion of amylose and a reduced proportion of amylopectin. As used herein, the term “starch” generally refers to the total starch of the grain or the starch prior to any fractionation that alters the ratio of amylose to amylopectin. The starch may be at least partly purified, i.e. it has been separated from at least one other component of the grain. As used herein, “substantially purified starch” means that at least 95% (w/w) of the dry weight of the composition is starch. Purified starch may be obtained from grain by a milling process, for example a wet milling process, which involves the separation of the starch from protein, oil and fibre. The initial product of the milling process is a mixture or composition of starch granules, and the invention therefore encompasses such granules, comprising the modified wheat starch as described herein, and the use thereof in the methods as described herein. Such granules comprise at least some of the wheat proteins found in wild-type wheat starch granules and therefore can be readily distinguished from the starch granules from other cereals.

In further embodiments, the altered starch has altered physical characteristics such as, for example, an increased or reduced gelatinisation temperature, altered swelling characteristics during or following gelatinisation, altered viscosity, an altered chain length distribution in the amylopectin, or any combination of these. Gelatinisation is the heat-driven collapse (disruption) of molecular order within the starch granule in excess water, with concomitant and irreversible changes in properties such as granular swelling, crystallite melting, loss of birefringence, viscosity development and starch solubilisation. High amylose starch from ae (amylose extender) mutants of maize showed a higher gelatinisation temperature than normal maize (Fuwa et al., 1999, Krueger et al., 1987). On the other hand, starch from barley sex6 mutants that lack starch synthase IIa activity had lower gelatinisation temperatures and the enthalpy for the gelatinisation peak was reduced when compared to that from control plants (Morell et al., 2003). The gelatinisation temperature of wild-type wheat starch is typically about 61° C. (Rahman et al, 2000) for the temperature of the first peak, defined as the onset temperature, as measured by differential scanning calorimetry. The increased or reduced gelatinisation temperature may be for the first peak of gelatinisation, the second peak, or both. One or more properties of the starch such as, for example, the enthalpy of gelatinisation, may be unaltered. The starch may have an increased or reduced gelatinisation temperature, preferably an increased gelatinisation temperature. For example, we have observed that the starch obtained from SBEIIa-reduced wheat has an increased gelatinization temperature, while that for SSIIa-reduced wheat has a reduced gelatinization temperature. The temperature of the first peak (apex) of gelatinisation as measured by differential scanning calorimetry may be increased or decreased by at least 3° C. or 5° C., preferably by at least 7° C. or 8° C. and more preferably by at least 10° C. compared to the temperature of the first peak for the corresponding starch from wild-type grain. In a particular embodiment, the increase or decrease is in the range of 3° C. to 12° C. Of particular note, the gelatinisation temperature may have a decreased temperature of onset of the first peak combined with an increased temperature of the peak apex. In another embodiment which is not mutually exclusive with the previous, the starch has an altered gelatinisation temperature for the first peak but exhibits a substantially unaltered temperature for the second peak, which corresponds to amylose-lipid dissociation, as determined by DSC. In a further embodiment, the starch exhibits a decreased enthalpy during gelatinisation, such as, for example, a decrease by at least 25% or at least 40% compared to that of corresponding wild-type wheat starch.

The starch may also be characterized by its swelling rate in heated excess water compared to wild-type starch. Swelling volume is typically measured by mixing either a starch or flour with excess water and heating to elevated temperatures, typically greater than 90° C. The sample is then collected by centrifugation and the swelling volume is expressed as the mass of the sedimented material divided by the dry weight of the sample. A low swelling characteristic is useful where it is desired to increase the starch content of a food preparation, in particular a hydrated food preparation.

The starch structure of the wheat of selected forms of the present invention may also differ in that the degree of crystallinity is reduced compared to normal starch isolated from wheat. The reduced crystallinity of a starch is also thought to be associated with enhanced organoleptic properties and contributes to a smoother mouth feel. Thus the starch may additionally exhibit reduced crystallinity resulting from reduced levels of activity of one or more amylopectin synthesis enzymes. Crystallinity is typically investigated by X-ray crystallography.

One measure of an altered amylopectin structure is the distribution of chain lengths, or the degree of polymerization, of the starch. The chain length distribution may be determined by using fluorophore-assisted carbohydrate electrophoresis (FACE) following isoamylase de-branching. The amylopectin of the starch of the invention may have a distribution of chain length in the range from 5 to 60 that is greater than the distribution of starch from wild-type plants upon debranching. Starch with longer chain lengths will also have a commensurate decrease in frequency of branching. Thus the starch may also have a distribution of longer amylopectin chain lengths in the amylopectin still present.

In another embodiment, the starch comprises an elevated level of resistant starch, with an altered structure indicated by specific physical characteristics. Such characteristics may include physical inaccessibility to digestive enzymes which may be by reason of having altered starch granule morphology, the presence of appreciable starch associated lipid, altered crystallinity, altered amylopectin chain length distribution, or any combination of these. The high proportion of amylose also contributes to the level of resistant starch.

The invention also provides starch from grain of the exemplified wheat plant comprising increased amounts of dietary fibre, preferably in combination with an elevated level of resistant starch. This increase is also at least in part a result of the high relative level of amylose.

The invention clearly extends to methods of producing the wheat starch described herein. In one embodiment, the method comprises the steps of obtaining wheat grain as described herein and extracting the starch from the grain. The wheat grain may be obtained by growing the wheat plants described herein and harvesting the grain, or from a producer of the grain or importer of the grain.

Foods, Beverages and Pharmaceutical Products

The invention also encompasses foods, beverages or pharmaceutical preparations produced with modified wheat or altered starch as described herein, preferably obtained from wheat plants that have reduced starch synthase or starch branching enzyme activity. Plants having reduced SBEIIa and SBEIIb activities may be produced by crossing a plant reduced for SBEIIa with a plant reduced for SBEIIb, or by introducing a transgene encoding a molecule that inhibits expression of both SBEIIa and SBEIIb genes. Such food production might include the making of flour, dough or other products that might be an ingredient in commercial food production.

Starch is the major source of carbohydrate in most human diets and the grain of the invention and products derived from it can be used to prepare food. The foods may be consumed by humans or animals, particularly mammalian animals, for example during livestock production or in pet-food. As used herein, “mammals” or “mammalian” refers to any member of the Mammalia. The grain derived from the altered wheat plant can be used readily in food processing procedures and therefore the invention includes milled, ground, kibbled, pearled or rolled grain or products obtained from the processed or whole grain of the wheat plant referred to above, including flour. These products may be then used in various food products, for example farinaceous products such as breads, cakes, biscuits and the like or food additives such as thickeners or binding agents or to make drinks, noodles, pasta or quick soups. The grain or products derived from the grain of the invention are particularly desired in breakfast cereals or as extruded products. The high amylose starches of the invention can also be used to form high strength gels that are useful in the confectionery industry or allow lower molding and curing times. They may also be used as a coating, for example, to reduce oil absorption in deep-fried potato or other foods.

Dietary Fibre

Dietary fibre, in this specification, is the carbohydrate and carbohydrate digestion products that are not absorbed in the small intestine of healthy humans but enter the large bowel. This includes resistant starches, β-glucans and other soluble and insoluble carbohydrate polymers. It is thought to comprise that portion of carbohydrates that are fermentable, at least partially, in the large bowel by the resident microflora.

The starch of the invention preferably contains relatively high levels of dietary fibre, more particularly amylose. The dietary fibre content of the grain of the present invention may or may not result solely from the increased relative endospermal amylose content.

Aspects of this invention might also arise from the combination of the aleurone layer and germ in combination with high levels of dietary fibre. Specifically, this may arise where higher relative levels of aleurone or germ are present in the grain. Where the wheat grain is slightly shrunken the endosperm is present in reduced amounts and the aleurone layer and the germ are present in relatively elevated amounts. Thus the wheat has a relatively high level of certain beneficial elements or vitamins in combination with elevated resistant starch. Such elements include divalent cations (including bioavailable Ca⁺⁺) and vitamins such as folate or antioxidants such as tocopherols or tocotrienols. One specific form of milled product might be one where the aleurone layer is included in the milled product. Particular milling process might be undertaken to enhance the amount of aleurone layer in the milled product. Thus, any product derived from grain milled or otherwise processed to include aleurone layer and germ will have the additional nutritional benefits, without the requirement of adding these elements from separate sources.

Resistant Starch

Resistant starch is defined as the sum of starch and products of starch digestion not absorbed in the small intestine of healthy humans but entering into the large bowel. Thus, resistant starch excludes products digested and absorbed in the small intestine. Resistant starches include physically inaccessible starch (RS1 form), resistant granules (RS2), retrograded starches (RS3) and chemically modified starches (RS4). The altered starch structure and in particular the high amylose levels of the starch of the invention give rise to an increase in resistant starch when consumed in food. The starch may be in an RS1 form, being somewhat inaccessible to digestion. Starch-lipid association, as measured by V-complex crystallinity, is also likely to contribute to the level of resistant starch. The level of resistant starch present in a food or other products is preferably measured in vitro as described in Example 13, or in vivo as described in Example 16.

It will be understood that one benefit of the present invention is that it provides for products that are of particular nutritional benefit and, moreover, it does so without the need to modify the starch or other constituents of the wheat grain. However it may be desired to make modifications to the starch or other constituent after extraction from the grain, and the invention encompasses such a modified constituent. Methods of modification are well known and include the extraction of the starch or other constituent by conventional methods and modification of the starches to increase the resistant form. The starch may be modified by treatment with heat and/or moisture, physically (for example ball milling), enzymatically (using for example α- or β-amylase, pullalanase or the like), chemical hydrolysis (wet or dry using liquid or gaseous reagents), oxidation, cross bonding with difunctional reagents (for example sodium trimetaphosphate, phosphorous oxychloride), esterification or carboxymethylation.

Glycemic Index

Glycemic Index (GI) relates to the rate of digestion of foods comprising the starch, and is a comparison of the effect of a test food with the effect of white bread or glucose on excursions in blood glucose concentration. The Glycemic Index is a measure of the likely effect of the food concerned on post-prandial serum glucose concentration and demand for insulin for blood glucose homeostasis. One important characteristic provided by foods of the invention is a reduced glycemic index. Furthermore, the foods may have a low level of final digestion and consequently be relatively low-kilojoule, or may be described as low energy-density foods. A low calorific product might be based on inclusion of flour produced from milled wheat grain, and so will be useful for reducing or controlling the weight of the animal, particularly a human. Such foods may have the effect of being filling, enhancing bowel health, reducing the post-prandial serum glucose and lipid concentration as well as providing for a low metabolisable energy food product.

Bread

In bread the altered wheat starch in the form of flour or wholemeal may substitute for 10% (w/w) or more of unaltered flour or wholemeal, preferably substituting at least 30% and even more preferably at least 50% of the unaltered flour or wholemeal. The formulation might therefore be, for example, flour 90 parts, altered wheat starch 10 parts, fat 2 parts, salt 2 parts, improver 1 part, yeast 2.5 parts. The production of the bread may be by a rapid dough technique or other techniques as is known by those skilled in the art.

Pasta Product

The altered wheat starch may be incorporated into a farinaceous based pasta product. The amount of altered wheat starch employed in the pasta composition may be in the range of 10-40% (w/w) or more based on the total weight of farinaceous material more particularly in the range of 15 to 35%. Suitable other farinaceous materials will readily be chosen by a person skilled in the art.

Other material may also be added to the composition for example dry or liquid eggs (yolks, whites, or both) or high protein substances such as milk protein or fish protein. Vitamins, minerals, calcium salts, amino acids, buffering agents such as disodium hydrogen phosphate, seasoning, gum, gluten or glyceryl monostearate may also be added.

In the preparation of pasta, the ingredients may first be dry blended until they are uniformly dispersed. Water is then added to the dry blend with continued mixing until a dough is obtained with is plastic enough to be sheeted or extruded but firm enough to cohere. The paste formulation will normally contain about 75 parts of dry farinaceous material and about 25 parts of water. These proportions will vary depending on such factors as the variety of flour employed, gluten quality, protein content, initial flour moisture and flour particle size. The pasta may be shaped and then dried using methods known in the art preferably with the starch component in an ungelatinised form.

Pharmaceutical Product

Compositions for oral delivery may be in the form of tablets, lozenges, aqueous or oily suspensions, granules, powders, emulsions, capsules, caplets, gelcaps, syrups or elixirs, for example. Orally administered compositions may contain one or more optional agents, for example, sweetening agents such as fructose, aspartame or saccharin; flavoring agents such as peppermint, oil of wintergreen, or cherry; coloring agents; and preserving agents, to provide a pharmaceutically palatable preparation. Moreover, where in tablet or pill form, the compositions may be coated to delay disintegration and absorption in the gastrointestinal tract thereby providing a sustained action over an extended period of time. Selectively permeable membranes surrounding an osmotically active driving compound are also suitable for orally administered compounds of the invention. In these later platforms, fluid from the environment surrounding the capsule is imbibed by the driving compound, which swells to displace the agent or agent composition through an aperture. These delivery platforms can provide an essentially zero order delivery profile as opposed to the spiked profiles of immediate release formulations. A time delay material such as glycerol monostearate or glycerol stearate may also be used. Oral compositions can include standard vehicles such as mannitol, lactose, starch, magnesium stearate, sodium saccharine, cellulose, magnesium carbonate, etc. Such vehicles are preferably of pharmaceutical grade.

Methods of Reducing Gene Activity

The expression and/or activity of SSIIa, SBEIIa, SBEIIb or other starch biosynthesis or modification genes may be altered by introducing one or more genetic variations into the wheat plant. As used herein, a “genetic variation” means any heritable alteration in the genome of the wheat plant which, in this context, affects the expression or activity of the gene of interest. Genetic variations include mutations such as point mutations, insertions, substitutions, inversions, duplications, translocations and preferably deletions, and the introduction of one or more transgenes into the genome.

The phrases “nucleic acid molecule” and “nucleic acid sequence” as used herein refer to a polymer of nucleotides, which may be single-stranded or double-stranded. It may comprise DNA such as, for example, genomic DNA or cDNA, or RNA, mRNA or any combinations of these. For introduction into wheat cells, a nucleic acid molecule may be chemically modified for improved delivery or stability, or protected as part of a vector such as a viral vector. The nucleic acid molecule may be obtained by cloning techniques or synthesized by techniques well known in the art. The nucleic acid molecule may comprise a coding strand or non-coding strand (antisense) or a combination of these such as, for example, in inverted repeat constructs. In reference to nucleic acid sequences which “correspond” to a gene, the term “correspond” refers to a nucleotide sequence relationship, such that the nucleotide sequence has a nucleotide sequence which is the same as the reference gene or an indicated portion thereof, or has a nucleotide sequence which is exactly complementary in normal Watson-Crick base pairing, or is an RNA equivalent of such a sequence, for example, an mRNA, or is a cDNA derived from an mRNA of the gene.

Nucleotide sequences are presented herein by a single strand sequence in the 5′ to 3′ direction, using the standard one letter nucleotide abbreviations. “Complementary” describes the relationship between two single-stranded nucleic acid molecules or sequences that anneal by base-pairing. For example, 5′-GACT-3′ pairs with its complement, 5′-AGTC-3′. “Homology” or “homologous” refers to sequence similarity or identity between two or more nucleotide sequences or two or more polypeptide sequences, according to the context. The term “percent identity” as applied to nucleotide sequences refers to the percentage of nucleotide matches between two nucleotide sequences aligned using a standardized algorithm such as, for example, the CLUSTAL V algorithm or the Blastn or BLAST 2 Sequences programs available from the National Center for Biotechnology Information, available on the Internet at www.ncbi.nlm.nih.gov/BLAST/, and preferably set at default parameters. In similar fashion, “percent identity” may refer to polypeptide sequences.

Reference herein to a “gene” including an SBEIIa, SSIIa, SBEIIb or other starch biosynthetic gene, or genes encoding antisense, co-suppression, ribozyme, duplex RNA molecules or the like, is to be taken in its broadest context and includes a classical genomic gene having a transcribed region associated with regulatory regions such as promoters and transcription terminators-polyadenylation sequences. The transcribed region includes transcribed but not translated sequences (untranslated sequences, UTR) and optionally may include a protein coding region or introns, which are spliced out to form a mature RNA, or any combination of these. A “gene” includes forms obtained from cDNA, corresponding to the exons, and RNA genes such as those found on RNA genomes. The term “gene” is also used to describe synthetic or fusion molecules encoding all or part of a functional product.

When present in a cell, preferably a wheat cell, a “gene” directs the “expression” of a “biologically active” molecule or “gene product”, which may be RNA or a polypeptide. This process is most commonly by transcription to produce RNA and translation to produce protein. Such a product may be subsequently modified in the cell. RNA may be modified by, for example, polyadenylation, splicing, capping, dicing into 21-23 nucleotide fragments, or export from the nucleus or by covalent or noncovalent interactions with proteins. Proteins may be modified by, for example, phosphorylation, glycosylation or lipidation. All of these processes are encompassed by the term “expression of a gene” or the like as used herein.

As used herein, the terms “wheat SBEIIa gene” “wheat SBEIIb gene” “wheat SSIIa gene” and related terms refer to the genes that have been identified from wheat that encode SBEIIa, SBEIIb or SSIIa enzymes, respectively, and homologous genes present in other wheat varieties. These include, but are not limited to, the gene sequences listed in Table 1. It would be understood that there is natural variation in the sequences of SBEIIa, SBEIIb and SSIIa genes from different wheat varieties. The homologous genes are readily recognizable by the skilled artisan. The degree of sequence identity between homologous SBEIIa genes or the proteins is thought to be at least 80%, similarly for SBEIIb genes or proteins. Analogous definitions apply to “wheat SSIIa gene” and the like.

The genes for use in the invention may be derived from a naturally occurring SBEIIa, SBEIIB, SSIIa or other starch biosynthetic gene by standard recombinant techniques. A “recombinant nucleic acid molecule” or like term as used herein refers to a sequence that is not naturally occurring or has a sequence that is made by an artificial combination of two or more otherwise separated segments of sequence. This artificial combination may be formed by chemical synthesis or, more commonly, by the artificial manipulation of isolated segments of nucleic acids, for example by genetic engineering techniques well known in the art. The term “recombinant” includes nucleic acids that have been altered solely by addition, substitution, or deletion of a portion of the nucleic acid. Frequently, a recombinant nucleic acid may include a nucleic acid sequence operably linked to a promoter sequence. Such a recombinant nucleic acid may be part of a vector that is used, for example, to transform a cell.

Generally, a gene may be subjected to mutagenesis to produce single or multiple nucleotide substitutions, deletions and/or additions such as, for example, codon modification. Nucleotide insertional derivatives of such genes include 5′ and 3′ terminal fusions as well as intra-sequence insertions of single or multiple nucleotides. Insertional nucleotide sequence variants are those in which one or more nucleotides are introduced into a predetermined site in the nucleotide sequence, although random insertion is also possible with suitable screening of the resulting product. Deletional variants are characterised by the removal of one or more nucleotides from the sequence. Substitutional nucleotide variants are those in which at least one nucleotide in the sequence has been removed and a different nucleotide inserted in its place. Such a substitution may be “silent” in that the substitution does not change the amino acid defined by the codon. Alternatively, conservative substituents are designed to alter one amino acid for another similar acting amino acid. Typical substitutions are those made in accordance with the following:

Suitable residues for conservative amino acid substitutions

Original Exemplary Residue Substitutions Ala Ser Arg Lys Asn Gln; His Asp Glu Cys Ser Gln Asn Glu Asp Gly Ala His Asn; Gln Ile Leu; Val Leu Ile; Val Lys Arg; Gln; Glu Met Leu; Ile Phe Met; Leu; Tyr Ser Thr Thr Ser Trp Tyr Tyr Trp; Phe Val Ile; Leu

Transgenes

The expression and/or activity of SBEIIa, SBEIIb, SSIIa or other starch biosynthesis or modification genes may be altered by introducing one or more transgenes into the wheat plant. A “transgene” as referred to herein has the normal meaning in the art of biotechnology and includes a genetic sequence which has been produced or altered by recombinant DNA or RNA technology and which has been introduced into the organism or cell, preferably wheat cell, of interest. The transgene may include genetic sequences derived from the organism or cell, for example an antisense sequence. The transgene typically includes an exogenous nucleic acid which is not derived from said organism or cell. “Transgenic” refers to the organism or cell containing a transgene, or the genetic sequence that was introduced into the organism or cell or its progenitor. “Non-transgenic” refers to the absence of any transgene in the genome. A transgene is preferably integrated into the genome of the organism or cell, for stable inheritance.

Those skilled in the art will be aware that expression of a gene or a complementary sequence thereto in a cell requires said gene to be placed in operable connection with a promoter sequence. The choice of promoter for the present purpose may vary depending upon the level of expression required and/or the tissue, organ and species in which expression is to occur, and is preferably an endosperm specific promoter that provides preferential expression in the developing endosperm of wheat.

Placing a nucleic acid molecule under the regulatory control of a promoter sequence means positioning said molecule such that expression is controlled by the promoter sequence. A promoter is usually, but not necessarily, positioned upstream, or at the 5′-end, of the nucleic acid molecule it regulates. Furthermore, the regulatory elements comprising a promoter are usually positioned within 2 kb of the start site of transcription of the gene. In the construction of heterologous promoter/structural gene combinations, it is generally preferred to position the promoter at a distance from the gene transcription start site that is approximately the same as the distance between that promoter and the gene it controls in its natural setting (i.e., the gene from which the promoter is derived). As is known in the art, some variation in this distance can be accommodated without loss of promoter function. Similarly, the preferred positioning of a regulatory sequence element with respect to a heterologous gene to be placed under its control is defined by the positioning of the element in its natural setting (i.e., the gene from which it is derived). Again, as is known in the art, some variation in this distance can also occur.

Examples of promoters suitable for use in gene constructs of the present invention include promoters derived from the genes of viruses, yeast, moulds, bacteria, insects, birds, mammals and plants, preferably those capable of functioning in plant cells, more preferably those capable of being expressed in the endosperm of wheat. The promoter may regulate expression constitutively, or differentially, with respect to the tissue in which expression occurs. Alternatively, expression may be differential with respect to the developmental stage at which expression occurs, or in response to external stimuli such as physiological stresses, or temperature.

The method of reducing SBEIIa, SBEIIb, SSIIa or other starch biosynthetic gene activity may comprise the step of introducing a transgene into a regenerable cell of wheat and regenerating a transgenic wheat plant from the transformed cell. The branching enzymes involved in synthesis of amylopectin include SBEI, SBEIIa and SBEIIb and the invention encompasses a reduced expression of SBEIIa alone or in combination with alteration of SBEIIb or SBEI expression, or a starch synthase activity in preference SSIIa. Therefore, the transgene(s) may inactivate more than one of these genes. Moreover, the inactivation of SBEIIb and/or SBEI and/or SSIIa may be direct, in that the transgene (e.g. encoding duplex RNA, antisense, or ribozyme RNA, see below) directly targets the SBEIIb or SBEI or SSIIa gene expression, or it may indirectly result in the alteration in the expression of SBEIIb or SBEI or SSIIa. For example, the transgene RNA may target only the SBEIIa gene/RNA in terms of sequence identity or basepairing but also result in reduction of SBEIIb or SBEI activity by altering protein stability or distribution in the endosperm. Additionally forms of the present invention reside in the combination of an altered activity of SBEIIa, SBEIIb or SSIIa and an alteration of one or more other amylopectin synthesis enzymes, which enzymes may include SSI, SSIIa, SSIIb, SSIII, phosphorylase and debranching enzymes such as isoamylase or pullulanase. Expression of any or all of these may be altered by introduction of a transgene.

Several DNA sequences are known for amylopectin synthesis genes in wheat, any of which can be the basis for designing transgenes for inactivation of the genes in wheat. These include SBEIIa (GenBank accession numbers Y11282, AF338431 and AF338432) SBEIIh (WO 00/15810, WO 01/62934) and SSIIa (GenBank Accession No AF155217 and WO 00/66745). The SBEI gene of wheat is described in Rahman et al., (1997) and Rahman et al., (1999). The Triticum tauschii sequence for SBEI, which is highly homologous to the wheat D genome SBEI gene, can be found in published Patent specification WO 99/14314. A cDNA sequence for SBEI of wheat can be accessed in the GenBank database under accession number AF076679. Homologues of other amylopectin synthesising genes from barley or other closely related species can also be used to modify gene expression levels in wheat. Such genes or fragments thereof can be obtained by methods well known in the art, including PCR amplification or hybridization to labeled probes.

“Stringent hybridization conditions” as used herein means that hybridization will generally occur if there is at least 90% and preferably at least 95% sequence identity between the probe and the target sequence. Examples of stringent hybridization conditions are overnight incubation in a solution comprising 50% formamide, 5×SSC (1×SSC=150 mM NaCl, 15 mM trisodium citrate), 50 mM sodium phosphate (pH 7.6), 5×Denhardt's solution, 10% dextran sulfate, and 20 μg/ml denatured sheared carrier DNA such as salmon sperm DNA, followed by washing the hybridization support in 0.1×SSC at approximately 65° C. Other hybridization and wash conditions are well known and are exemplified in Sambrook et al, Molecular Cloning: A Laboratory Manual, Second Edition, Cold Spring Harbor, N.Y. (1989), particularly chapter 11.

The region(s) of the homologues used in preparing the transgene construct should have at least 85% identity to the corresponding wheat gene or gene region, preferably at least 90% and even more preferably 95-100% identity in the appropriate region. It is also preferred that the transgene specifically target the amylopectin synthesis genes expressed in the endosperm of wheat and have less or minimal effect on amylopectin synthesis elsewhere in the plant. This may be achieved by use of suitable regulatory sequences such as endosperm-specific promoters in the transgene.

Antisense

Genetic engineering approaches to altering, in particular specifically reducing, gene activity in plants such as wheat are well known in the art. These methods include the introduction of gene constructs for expression of a suitable antisense molecule that comprises nucleotides that are complementary in sequence to at least part of the RNA of the target gene and can hybridize with it. Antisense molecules are thought to interfere with the translation or processing or stability of the mRNA of the target gene, thereby inactivating expression of the gene. Methods of devising antisense sequences are well known in the art and examples of these can be found in U.S. Pat. No. 5,190,131, European patent specification 0467349-A1, European patent specification 0223399-A1 and European patent specification 0240208, which are incorporated herein by reference. The use of antisense methods in plants has been reviewed by Bourque (1995) and Senior (1998). Bourque lists a large number of examples of gene inactivation using antisense sequences in plant systems. She also states that attaining 100% inhibition of an enzyme activity may not be necessary as partial inhibition will more than likely result in measurable change in the system. Senior (1998) states that antisense methods are now a very well established technique for manipulating gene expression in plants.

Antisense molecules for wheat SBEIIa, SBEIIb, SSIIa, SBEI or other starch biosynthesis or modification genes can be based on the wheat mRNA sequences or derived from homologous DNA or mRNA sequences obtained from other species, for example barley. The antisense sequences may correspond to all or part of the transcripts of any of these genes or for sequences that effect control over their expression, for example their splicing. The antisense sequence may correspond to the targeted coding region of the wheat SBEIIa, SSIIa, SBEIIb or other gene, or the 5′-untranslated region (UTR) or the 3′-UTR or combination of these. It may be complementary in part to intron sequences, which may be spliced out during or after transcription, preferably only to exon sequences of the target gene. In view of the generally greater divergence of the UTRs, targeting these regions provides greater specificity of gene inhibition. In particular embodiments, the length of the antisense sequence is at least 19 contiguous nucleotides, at least 50, at least 100, at least 200, at least 500 or at least 1000 nucleotides corresponding to the complement of the gene RNA sequence. The full-length sequence complementary to the entire gene transcript may be used. In a particular embodiment, the length of the antisense sequence is 100-2000 nucleotides. In further embodiments, the degree of sequence identity of the antisense sequence to the complement of the targeted transcript is at least 85%, at least 90% or 95-100%. The antisense RNA molecule may of course comprise unrelated sequences which may function to stabilize the molecule.

Cosuppression

Another molecular biological approach that may be used is co-suppression. The mechanism of co-suppression is not well understood but is thought to involve post-transcriptional gene silencing (PTGS) and in that regard may be very similar to many examples of antisense suppression. It involves introducing an extra copy of a gene or a fragment thereof into a plant in the sense orientation with respect to a promoter for its expression. The size of the sense fragment, its correspondence to target gene regions, and its degree of sequence identity to the target gene are as for the antisense sequences described above. In some instances the additional copy of the gene sequence interferes with the expression of the target plant gene. Reference is made to Patent specification WO 97/20936 and European patent specification 0465572 for methods of implementing co-suppression approaches.

Double Stranded RNA-Mediated Gene Silencing

A further method that might be employed to introduce genetic variation into the wheat plant is duplex or double stranded RNA mediated gene silencing. This method also involves PTGS. In this method a DNA is introduced that directs the synthesis of an at least partly double stranded RNA product(s) with homology to the target gene to be inactivated. The DNA therefore comprises both sense and antisense sequences that, when transcribed into RNA, can hybridize to form the double-stranded RNA region. In a preferred embodiment, the sense and antisense sequences are separated by a spacer region that comprises an intron which, when transcribed into RNA, is spliced out. This arrangement has been shown to result in a higher efficiency of gene silencing. The double-stranded region may comprise one or two RNA molecules, transcribed from either one DNA region or two. The presence of the double stranded molecule triggers a response from an endogenous plant system that destroys both the double stranded RNA and also the homologous RNA transcript from the target plant gene, efficiently reducing or eliminating the activity of the target gene. Reference is made to Australian Patent specification 99/29514-A and Patent specification WO 99/53050 for methods of implementing this technique. In particular embodiments, the length of the sense and antisense sequences that hybridise are at least 19 contiguous nucleotides, at least 30, at least 50, at least 100, at least 200, at least 500 or at least 1000 nucleotides. The full-length sequence corresponding to the entire gene transcript may be used. In a particular embodiment, the lengths are in the range 100-2000 nucleotides. In further embodiments, the degree of sequence identity of the sense and antisense sequences to the targeted transcript is at least 85%, at least 90% or 95-100%. The RNA molecule may of course comprise unrelated sequences which may function to stabilize the molecule. The RNA molecule may be expressed under the control of a RNA polymerase II or RNA polymerase III promoter. Examples of the latter include tRNA or snRNA promoters. The double-stranded RNA molecule may also comprise sequences from more than one gene, joined together, and thereby target multiple genes.

Ribozymes

The genetic variation responsible for the desired inactivation of gene expression in wheat may comprise a nucleic acid molecule encoding one or more ribozymes. Ribozymes are RNA molecules with enzymatic or catalytic function that can cleave other RNA molecules at specific sites defined by one or often two hybridizing sequences. The cleavage of the RNA inactivates the expression of the target gene. The ribozymes may also act as an antisense molecule, which may contribute to the gene inactivation. The ribozymes contain one or more catalytic domains, preferably of the hammerhead or hairpin type, between the hybridizing sequences. Other ribozyme motifs may be used including RNAseP, Group I or II introns, and hepatitis delta virus types. Reference is made to European patent specification 0321201 and U.S. Pat. No. 6,221,661. The use of ribozymes to inactivate genes in transgenic plants has been demonstrated, for example by Wegener et al (1994).

Genetic Constructs/Vectors

The invention also provides isolated nucleic acid molecules comprising RNA or DNA, preferably DNA, which encode the gene-inhibiting molecule. In certain embodiments, the nucleic acid molecules encode antisense, sense (co-suppression), double-stranded RNA or ribozyme molecules which target the wheat SBEIIa gene sequence and which inactivate its expression in endosperm of wheat grain. The invention also provides genetic constructs comprising or encoding the isolated nucleic acid molecule, comprising one or more regulatory elements such as promoters, enhancers and transcription termination or polyadenylation sequences. Such elements are well known in the art. The genetic constructs may also comprise intron sequences that aid expression of the transgene in plants, particularly in monocotyledonous plants such as wheat. The term “intron” is used in its normal sense as meaning a genetic segment that is transcribed but does not encode protein and which is spliced out of an RNA before translation. Introns may be incorporated in a 5′-UTR or a coding region if the transgene encodes a translated product, or anywhere in the transcribed region if it does not.

The invention further provides vectors, for example plasmid vectors, comprising the genetic constructs. The term “vector” includes an expression vector, being capable of in vitro or in vivo expression, and a transformation vector, capable of being transferred from one cell or organism to another. The vectors comprise sequences that provide for replication in cells, for example in prokaryotic cells such as E. coli or Agrobacterium. In a particular embodiment, the vector is a binary vector comprising a T-DNA sequence, defined by at least one T-DNA border sequence, that can be introduced into wheat cells. The invention further provides cells comprising the vectors, for example Agrobacterium or wheat cells which may be regenerable cells such as the cells of the scutellum of immature embryos. Alternatively, the cells may be transformed wheat cells comprising the transgene.

Promoters/Terminators

In another embodiment, the transgene or other genetic construct of the invention includes a transcriptional initiation region (promoter) that may provide for regulated or constitutive expression in the endosperm of wheat. The promoter may be tissue specific, conferring expression selectively or exclusively in the endosperm. The promoter may be selected from either endosperm-specific (such as High Molecular Weight Glutenin promoter, the wheat SSI promoter, wheat SBEII promoter, wheat GBSS promoter) or promoters not specific for the endosperm (such as ubiquitin promoter or CaMV35S or enhanced 35S promoters). The promoter may be modulated by factors such as temperature, light or stress. Ordinarily, the promoter would be provided 5′ of the genetic sequence to be expressed. The construct may also contain other elements that enhance transcription such as the nos 3′ or the ocs 3′ polyadenylation regions or transcription terminators. The regions of DNA illustrated will be incorporated into vectors containing suitable selectable marker gene sequences and other elements, or into vectors that are co-transformed with vectors containing these sequences.

Transformation Methods for Wheat

Methods for transformation of monocotyledonous plants such as wheat, that is for introducing genetic variation into the plant by introduction of an exogenous nucleic acid, and for regeneration of plants from protoplasts or immature plant embryos are well known in the art, see for example, Becker et al 1994, Cheng et al 1997, He et al 1994, Hess et al 1990, Nehra et al 1994, Vasil et al 1992, Vasil et al 1993, Weeks et al 1993, Weir et al 2001, Australian Patent Application No. 75460/94, European Patent Application No. 709462, International Patent Publication Nos. WO93/04178, WO89/12012, WO94/13822 and WO99/14314. Vectors carrying the desired nucleotide sequence or genetic construct and a selectable marker may be introduced into regenerable wheat cells of tissue cultured plants or explants, or suitable plant systems such as protoplasts. The selectable marker gene may provide antibiotic or herbicide resistance to the wheat cells, or allow the utilization of substrates such as mannose. The selectable marker preferably confers asulam, geneticin or hygromycin resistance to the wheat cells. The regenerable wheat cells are preferably from the scutellum of immature embryos, mature embryos, callus derived from these, or the meristematic tissue.

The transformed plant may contain a selectable marker gene, or such gene may be removed during or after regeneration, for example by excision of the selectable marker gene out of the genome or by segregation of the selectable marker gene away from the starch synthase or starch branching enzyme inhibiting transgene or the more preferably SBEIIa, SBEIIb or SSIIa inhibiting transgene.

Plants where the transgene or mutation has been integrated into a chromosome can be screened for by, for example, using a suitable nucleic acid probe specific for the transgene or phenotypic observation. Any of several methods may be employed to determine the presence of a transformed plant. For example, polymerase chain reaction (PCR) may be used to amplify sequences that are unique to the transformed plant, with detection of the amplified products by gel electrophoresis or other methods. DNA may be extracted from the plants using conventional methods and the PCR reaction carried out using primers that will distinguish the transformed and non-transformed plants. For example, primers may be designed that will amplify a region of DNA from the transformation vector reading into the construct and the reverse primer designed from the gene of interest. These primers will only amplify a fragment if the plant has been successfully transformed. An alternative method to confirm a positive transformant is by Southern blot hybridization, well known in the art. Plants which are transformed or mutant may also be identified i.e. distinguished from non-transformed or wild-type plants by their phenotype, for example conferred by the presence of a selectable marker gene, or the presence of a particular protein by immunological methods, or by the absence of a protein, for example that absence of the SBEIIa, SSIIa or SBEIIb protein in the endosperm as detected by ELISA assay or Western blot analysis. An indication used in screening such plants might also be by observation of the phenotypic traits of the grain, for example by visual inspection or measurement of shrunken grain, or testing for elevated amylose content, or checking microscopically for the presence of birefringence.

Mutation

Introduction of the genetic variation leading to reduced activity of the SBEIIa enzyme or other starch biosynthetic enzyme in the wheat endosperm may also be achieved by the appropriate mutations within the respective gene or regulatory sequences of the gene. In the context of this application, an “induced mutation” is an artificially induced genetic variation which may be the result of chemical, radiation or biologically-based mutagenesis, for example transposon or T-DNA insertion. The extent to which the gene is inhibited will to some degree determine the characteristics of the starch made. The mutations may be truncation or null mutations and these are known to have a significant impact on the nature of the starch, however an altered starch structure will also result from a leaky mutation that sufficiently reduces amylopectin synthesis enzyme activity to provide the characteristic of interest in the starch or grain of wheat. Other chromosomal rearrangements may also be effective and these might include insertions, deletions, inversions, duplication or point mutations. A “null mutation” as used herein refers to a mutation which results in the complete or near complete loss of activity of the gene of interest such as, for example, where the gene activity can no longer be detected.

The SBEIIa gene is located on the long arm of chromosome 2. It is preferred that mutations to the gene or other genes, particularly deletion mutations, are localised to the gene of interest, for example the SBEIIa gene or perhaps extended to the linked SBEIIb gene in the case of a double mutant. A gene in this context includes the promoter region and transcription termination/polyadenylation signals as well as the transcribed region. The transcribed region includes the protein coding region(s) and the 5′ untranslated and 3′ untranslated regions of the mRNA as well any intron regions that may be present. Mutations to a gene may be in any region of the gene or a combination of regions and might extend from altering only one nucleotide, for example a frameshift mutation in the coding region, to deletion of the entire gene. Plants which are homozygous for the genetic variation are preferred.

Deletions may be restricted in size in the order of one or a few hundred, perhaps 500, kilobases. In certain embodiments, the deletion extends to less than a few thousand kilobases, or less than 5 thousand kilobases. Whilst the invention may encompass larger deletions including much of the long arm of chromosome 2 of the respective genome these are not preferred because the long arm of chromosome 2 has a number of other genes localised thereon that impact on the vigour of the wheat plant. Accordingly, where large deletions occur, these impact adversely on the vigour of the plant and hence on its commercial viability, and it is desired that at least a majority of the long arm of chromosome 2 is present. In a preferred embodiment, the majority of the long arm of chromosome 2A is present.

Mutagenesis can be achieved by chemical or radiation means, for example EMS or sodium azide (Zwar and Chandler, 1995) treatment of seed, or gamma irradiation. Isolation of mutants may be achieved by screening mutagenised plants or seed. For example, a mutagenized population of wheat may be screened for high amylose content in the grain and/or longer than normal amylopectin chain length distribution, or loss of the SBEIIa, SBEIIb or SSIIa protein by ELISA, or for altered grain morphology (Green et al., 1997). Screening is preferably done in a wheat genotype that already lacks one of the SBE activities, for example in a SBEIIb-negative background. Alternatively, the mutation may be identified using techniques such as “tilling” in a population mutagenised with an agent such as EMS (Slade et al, 2005). Such mutations may then be introduced into desirable genetic backgrounds by crossing the mutant with a plant of the desired genetic background and performing a suitable number of backcrosses to cross out the originally undesired parent background.

In another embodiment, the mutation affects the expression or activity of both SBEIIa and SBEIIb genes in wheat. Identifying such a mutation is aided by the unexpected finding that the two genes are closely linked in wheat, in contrast to maize or rice. Deletions in one gene may readily extend to the other gene, providing a null allele (null mutation) for both genes. This knowledge also aids the screening of natural variants that are mutant in both genes on at least one genome of wheat, and more readily allows screening to produce wheat with combined mutations in both genes in two or three genomes. Such wheat provides a high amylose, non-transgenic source of wheat grain and products therefrom.

Mutations in the genes encoding the SSIIa, SBEIIb, SBEIIa or other enzymes involved in amylopectin synthesis will generally cause an increased proportion of amylose content. The amount of amylose per individual grain may be increased as a consequence of diverted carbon flow from amylopectin to amylose, or it may be decreased if there is a significant decrease in starch production per grain. In either case, the relative level of amylose as a percentage of starch increases.

Birefringence is the ability of a substance to refract light in two directions; this produces a dark cross called a “maltese cross” on each starch granule when viewed with a polarizing microscope. Birefringence is an indicator of the degree of ordered structural organization of the polymers within the granules (Thomas and Atwell, 1999). Loss of birefringence in starch granules is generally well correlated with increased amylose content.

It will be understood that whilst various indications have been given as to aspects of the present invention, the invention may reside in combinations of two or more aspects of the present invention.

EXAMPLES Example 1 Materials and Methods

Starch Granule Morphology and Size Distribution

Starch granule morphology was examined by light microscopy with and without polarized light, looking for irregular shapes and irregular crystallinity, in particular loss of birefringent “Maltese cross” under polarized light. Light microscopy results may be confirmed by scanning electron microscopy (SEM) of the starch granules. To do this, purified starch granules are sputtered with gold and scanned at 15 kV at room temperature.

Granule size distribution (by volume) of the starch slurries was determined using a laser diffraction particle size analyser (Mastersizer 2000, Malvern Instruments, Malvern, England) and defined as the percentage of small B-type starch granules in each sample.

Carbohydrate Determination and Analysis

Starch was extracted from wheat grain as follows. Grain was milled in a Quadramat Jnr. mill (Brabender Quadramat Jnr. Mill, Cyrulla's Instruments, Sydney, NSW Australia) after conditioning the grains to a moisture content of 14%. Starch was isolated by a protease extraction method (Morrison et al., 1984) followed by water washing and removal of the tailings. In some cases, starch was isolated by first making a dough and separating starch from gluten using a Glutomatic 2200 (Perten Instruments, Huddinge, Sweden), followed by extensive water washing and removal of the tailings. Starch analyses other than granule size and morphology were made on freeze-dried samples (Dynavac Freeze Drier). In other experiments, total starch was isolated from wheat grain using the method of Schulman et al. (1991). Starch content was determined using the total starch analysis kit supplied by Megazyme (Bray, Co Wicklow, Republic of Ireland).

The amylose content of starch samples was determined in some experiments by the calorimetric (iodometric) method of Morrison and Laignelet (1983) with slight modifications as follows. Approximately 2 mg of starch was weighed accurately (to 0.1 mg) into a 2 ml screw-capped tube fitted with a rubber washer in the lid. To remove lipid, 1 ml of 85% (v/v) methanol was mixed with the starch and the tube heated in a 65° C. water bath for 1 hour with occasional vortexing. After centrifugation at 13,000 g for 5 min the supernatant was carefully removed and the extraction steps repeated. The starch was then dried at 65° C. for 1 hour and dissolved in urea-dimethyl sulphoxide solution (UDMSO; 9 volumes of dimethyl sulphoxide to 1 volume of 6 M urea), using 1 ml of UDMSO per 2 mg of starch (weighed as above). The mixture was immediately vortexed vigorously and incubated in a 95° C. water bath for 1 hour with intermittent vortexing for complete dissolution of the starch. An aliquot of the starch-UDMSO solution (50 μl) was treated with 20 μl of I₂-KI reagent that contained 2 mg iodine and 20 mg potassium iodide per ml of water. The mixture was made up to 1 ml with water. The absorbance of the mixture at 650 nm was measured by transferring 200 μl to microplate and reading the absorbance using an Emax Precision Microplate Reader (Molecular Devices, USA). Standard samples containing from 0 to 100% amylose and 100% to 0% amylopectin were made from potato amylose and corn (or potato) amylopectin (Sigma) and treated as for the test samples. The amylose content (percentage amylose) was determined from the absorbance values using a regression equation derived from the absorbances for the standard samples.

The amylose content of starch was determined in some cases by a Sepharose column separation method as follows. Approximately 10 mg of starch was dissolved in 3.0 ml of 1N NaOH (de-gassed) by incubation at 37° C. for 30 min. The starch solution was centrifuged for 15 min to spin down the undissolved components. The supernatant was loaded on to a Sepharose CL2B column at a pump speed of 1 ml/min. The column was run using 10 mM NaOH as buffer and fifty fractions of 2.5 ml each were collected. The pH of fractions was adjusted to 4.5 with 35 μl of 1 M HCl. An aliquot (250 μl) of each sample was transferred into a tube followed by the addition of 250 μl of Starch reagent (Starch assay kit, Sigma). The controls included a starch assay reagent blank containing only starch reagent (250 μl) and water (250 μl), a glucose assay reagent blank containing only 500 μl water, a sample blank containing only 250 μl starch sample and 250 μl water and a sample test containing only 250 μl starch reagent and 250 μl starch sample. The samples and the controls were incubated at 60° C. for 60 min, and then 200 μl of each transferred to a new tube followed by addition of 1 ml of glucose reagent (starch assay kit, Sigma) and incubation at 37° C. for 30 min. The absorbance at 340 nm was used to determine the quantity of starch (mg) in each fraction according to the instructions supplied with the kit. The chromatogram of starch samples showed two peaks eluted from the Sepharose column. The amylose content (second peak) of each sample was calculated as a percentage of the total amount of starch within both of the peaks.

Analysis of the amylose/amylopectin ratio of non-debranched starches may also be carried out according to Case et al., (1998) or by an HPLC method for separating debranched starches, using 90% (v/v) DMSO, as described by Batey and Curtin (1996).

The distribution of chain lengths in the amylopectin of the starch was analysed by fluorophore assisted carbohydrate electrophoresis (FACE) using a capillary electrophoresis unit according to Morell et al (1998), after debranching of the starch samples. For example, amylopectin chain length distribution was measured using a P/ACE 5510 capillary electrophoresis system (Beckman Coulter, NSW Australia) with argon laser-induced fluorescence (LIF) detection. Molar difference plots were generated by subtracting the normalized chain length distribution for modified starch from the normalized distribution for starch from an isogenic non modified control.

The gelatinisation temperature profiles of starch samples were measured in a Pyris 1 differential scanning calorimeter (Perkin Elmer, Norwalk Conn., USA). The viscosity of starch solutions was measured on a Rapid-Visco-Analyser (RVA, Newport Scientific Pty Ltd, Warriewood, Sydney), using conditions as reported by Batey et al., 1997. The parameters that may be measured include peak viscosity (the maximum hot paste viscosity), holding strength, final viscosity and pasting temperature. Pasting properties were measured using the Rapid Visco Analyser as follows. Starch (3.0 g) was added to distilled water (25.0 ml) in the DSC pan and the RVA run profile was: 2 mins at 50° C., heat for 6 mins to 95° C., hold at 95° C. for 4 mins, cool for 4 mins to 50° C., hold at 50° C. for 4 mins. The measured parameters were: Peak viscosity at 95° C., Holding strength at end of 95° C. holding period, Breakdown=Peak Viscosity—Holding strength, Final viscosity at end of 50° C. holding period, Setback=Final Viscosity—Holding strength. The software Thermocline for Windows version 2.2 (Newport Scientific Pty Ltd, NSW Australia) was used for collection and analysis of data.

The swelling volume of flour or starch was determined according to the method of Konik-Rose et al (2001). The uptake of water was measured by weighing the sample prior to and after mixing the flour or starch sample in water at defined temperatures (for example, 90° C.) and following collection of the gelatinized material.

Enzyme Assay

Total starch synthase activity in endosperm may be measured by extraction of proteins and assay by the methods described in Libessart et al. (19995) or Cao et al. (1999). The assays use ¹⁴C labeled ADPG substrate and measure incorporation of the monomer into starch polymers. Individual isoforms of starch synthase in extracts may be separated by gel electrophoresis and assayed in-gel (zymogram) as follows. Extracts from developing seeds may be prepared using 50 mM potassium phosphate buffer, pH7.5, 5 mM EDTA, 20% glycerol, 10 μM Pefabloc and 0.05 mM dithiothreitol (DTT). After grinding the seeds to a pulp in the buffer, the mixture is centrifuged at 14,000 g for 15 min at 4° C. and the supernatant drawn off. The protein concentration in the supernatant may be measured using Coomassie Protein Reagent or other standard means. Storage of the extracts is at −80° C. if the protein extracts are to be run on native gels. For denaturing gel electrophoresis, 100 μl of extract is mixed with SDS and β-mercaptoethanol and the mixtures are incubated in boiling water for 4 min to denature the proteins. Electrophoresis is carried out in standard denaturing polyacrylamide gels using 8% polyacrylamide separating gels overlaid with 4.5% polyacrylamide stacking gels. After electophoresis, the proteins may be renatured by soaking the gels in 40 mM Tris-HCl buffers for a minimum of 2 hr, changing the buffer every 30 min and using at least 100 mL of buffer for each buffer change. For non-denaturing gels, the denaturing step with SDS and β-mercaptoethanol is omitted and SDS omitted from the gels. A starch synthase assay buffer including Tris-glycine (25 mM Tris, 0.19M glycine), 0.133M ammonium sulphate, 10 mM MgCl₂, 6701 g/mL BSA and 1 mM ADPG substrate may be used to detect starch synthase bands, followed by staining with 2% KI, 0.2% 12 iodine solution to detect the starch product.

Alternatively, starch synthase or other starch biosynthetic enxymes may be detected in extracts from seeds using specific antibodies (ELISA).

Example 2 Genetic Constructs for the Alteration of Wheat SBEIIA and SBEIIB Expression

Duplex-RNA (dsRNA) constructs were made to reduce the expression of either the SBEIIa or SBEIIb genes of wheat. In such constructs, the desired nucleic acid sequence corresponding to part of the SBEIIa or SBEIIb genes occurred in both the sense and antisense orientations relative to the promoter so that the expressed RNA comprised complementary regions that were able to basepair and form a duplex or double-stranded RNA. A spacer region between the sense and antisense sequences comprised an intron sequence which, when transcribed as part of the RNA in the transformed plant, would be spliced out to form a tight “hairpin” duplex structure. The inclusion of an intron has been found to increase the efficiency of gene silencing conferred by duplex-RNA constructs (Smith et al, 2000). The desired nucleic acid was linked to a high molecular weight glutenin (HMWG) promoter sequence (promoter of the Dx5 subunit gene, Accession No. X12928, Anderson et al., 1989) and terminator sequence from the nopaline synthase gene from Agrobacterium (nos3′). This provided endosperm specific expression of the dsRNA sequences.

The SBEIIa duplex-RNA construct contained 1536 bp of nucleotide sequence amplified by PCR from the wheat SBEIIa gene (GenBank Accession number AF338431, see FIG. 1). This included a 468 bp sequence that comprised the whole of exons 1 and 2 and part of exon 3 (nucleotide positions 1058 to 1336, 1664 to 1761 and 2038 to 2219 in FIG. 1), with EcoRI and KpnI restriction sites on either side (fragment 1), a 512 bp sequence consisting of part of exons 3 and 4 and the whole of intron 3 of SBEIIa (nucleotide positions 2220 to 2731 in FIG. 1) with KpnI and SacI sites on either side (fragment 2) and a 528 bp fragment consisting of the complete exons 1, 2 and 3 of SBEIIa (nucleotide positions 1058 to 1336, 1664 to 1761 and 2038 to 2279 in FIG. 1) with BamHI and SacI sites on either side (fragment 3). Fragments 1, 2 and 3 were then ligated so that the sequence of fragment 3 was ligated to fragment 2 in the antisense orientation relative to fragment 1. The duplex-RNA constructs were initially generated in the vector pDVO3000 which contains the HMWG promoter sequence and nos3′ terminator. The gene construct in the vector pDVO3000 was designated pDVO3-IIa and the duplex-RNA gene designated ds-SBEIIa.

The strategy for the SBEIIb duplex-RNA construct was similar. The SBEIIb construct contained a fragment of 1607 bp amplified by PCR from the wheat SBEIIb gene (sequence is outlined in FIG. 2). This included a 471 bp sequence that comprised the whole of exons 1 and 2 and part of exon 3 (nucleotide positions 489 to 640, 789 to 934 and 1598 to 1769 in FIG. 2), with EcoRI and KpnI restriction sites on either side (fragment 1), a 589 bp sequence consisting of part of exons 3 and 4 and the whole of intron 3 of SBEIIb (nucleotide positions 1770 to 2364 in FIG. 2) with KpnI and SacI sites on either side (fragment 2) and a 528 bp fragment consisting of the complete exons 1, 2 and 3 of SBEIIb (nucleotide positions 489 to 640, 789 to 934 and 1598 to 1827 in FIG. 2) with BamHI and SacI sites on either side (fragment 3). Fragments 1, 2 and 3 were then ligated so that the sequence of fragment 3 was ligated to fragment 2 in the antisense orientation relative to fragment 1. The SBEIIb duplex-RNA gene construct in the vector pDVO3000 was designated pDVO3-IIb and the duplex-RNA gene designated ds-SBEIIb. The constructs are shown schematically in FIG. 3.

Each of the ds-RNA expression cassettes was then cut out with the restriction enzyme XhoI and inserted into the binary transformation vectors pGB53 and pBIOS340. pGB53 was created from pSB11 (Komari et al., 1996) by the introduction of the gene encoding asulam resistance (sul) driven by the rice actin promoter, leaving a unique XhoI site adjacent to the right T-DNA border for the introduction of a gene of interest. Similarly, pBIOS340 was created from pSB1 (Komari et al., 1996) by the introduction of an nptII gene encoding kanamycin and geneticin resistance, driven by the rice actin promoter, again leaving a unique XhoI site adjacent to the right border. The SBEIIa constructs in pGB53 and pBIOS340 were designated pCL51 and pCL59, respectively, and the SBEIIb constructs in pGB53 and pBIOS340 were designated pCL54 and pCL60, respectively.

Example 3 Transformation of Wheat

Genetic constructs for transformation of wheat were introduced by electroporation into the disarmed Agrobacterium tumefaciens strain LBA4404 carrying the vir plasmid pAL4404 and pSB1, with subsequent selection on media with spectinomycin. Transformed Agrobacterium strains were incubated on solidified YEP media at 27° C. for 2 days. Bacteria were then collected and re-suspended in TSIM1 (MS media with 100 mg/l myo-inositol, 10 g/l glucose, 50 mg/l MES buffer pH5.5) containing 400 mM acetosyringone to an optical density of 2.4 at 650 nm for wheat inoculation.

Wheat plants (variety NB1, a Spring wheat variety obtained from Nickerson Seeds Ltd, Rothwell, Lincs.) were grown in a glasshouse at 22/15° C. day/night temperature with supplemented light to give a 16 hour day. Tillers were harvested approximately 14 days post-anthesis (embryos approximately 1 mm in length) to include 50 cm tiller stem. All leaves were then removed from the tillers except the flag leaf, which was cleaned to remove contaminating fungal spores. The glumes of each spikelet and the lemma from the first two florets were then carefully removed to expose the immature seed. Generally, only these two seed in each spikelet were uncovered. This procedure was carried out along the entire length of the inflorescence. The ears were then sprayed with 70% IMS as a brief surface sterilization.

Agrobacterium suspensions (1 μl) were inoculated using a 10 μl Hamilton syringe into the immature seed approximately at the position of the scutellum:endosperm interface so that all exposed seed were inoculated. The tillers were then placed in water, covered with a translucent plastic bag to prevent seed dehydration, and placed in a lit incubator for 3 days at 23° C., 16 hr day, 45 μEm⁻²s⁻¹PAR. After 3 days of co-cultivation, the inoculated immature seed were removed and surface sterilized with 70% ethanol (30 sec), then 20% bleach (Domestos, 20 min), followed by thorough washing in sterile distilled water. Immature embryos were aseptically isolated and placed on W3 media (MS supplemented with 20 g/l sucrose and 2 mg/l 2,4-D and solidified with 6 g/l Type I agarose, Sigma) with the addition of 150 mg/l Timentin (W3T) and with the scutellum uppermost (20 embryos per plate). Cultures were placed at 25° C. in the light (16 hour day, 80 μEm⁻²s⁻¹PAR). The development of the embryonic axis on the embryos was assessed about 5 days after isolation and the axis was removed where necessary to improve callus production. The embryos were maintained on W3T for 4 weeks, with a transfer to fresh media at 2 weeks post-isolation and assessed for embryogenic capacity.

After 4 weeks growth, callus derived from the inoculated embryos was very similar to control callus obtained from uninoculated embryos plated on W3T medium. Presence of the bacteria did not appear to have substantially reduced the embryogenic capacity of the callus derived from the inoculated embryos. Embryogenic calli were transferred to W3 media with 2 mg/l Asulam (where pGB53 derivatives were used) or geneticin at 25 mg/l (pBIOS340 derivatives) and 150 mg/l Timentin (W32AT). Calli were maintained on this media for a further 2 weeks and then each callus was divided into 2 mm-sized pieces and re-plated onto W32AT. Control embryos derived from inoculations with the LBA4404 without binary vector constructs did not produce transformed callus on selection media.

After a further 2 weeks culture, all tissue was assessed for development of embryogenic callus: any callus showing signs of continued development after 4 weeks on selection was transferred to regeneration media (RMT—MS with 40 g/l maltose and 150 mg/l Timentin, pH 5.8, solidified with 6 g/1 agarose, Sigma type 1). Shoots were regenerated within 4 weeks on this media and then transferred to MS30 with 150 mg/l Timentin for shoot elongation and rooting. Juvenile plants were then transferred to soil mixture and kept on a misting bench for two weeks and finally transferred to a glasshouse.

A total of 3217 embryos using pCL54 or pCL60 (ds-SBEIIb) and 2010 embryos using pCL51 or pCL59 (ds-SBEIIa) were treated by this method and 61 plants were regenerated from calli for the IIb transformation and 31 plants regenerated from calli for the IIa transformation. Survival on selection medium suggested that they were successfully transformed with the gene construct. A large majority, but not all, of the plants that were transformed with the selectable marker gene would be expected to integrate the SBEIIa or SBEIIb inhibitory gene; these could readily be distinguished as described in the following examples.

The recovery of multiple, stable integration events with good regeneration potential from the experiments indicated that the seed inoculation transformation method used here was as efficient as other reported methods for wheat. Alternative Agrobacterium strains such as strain AGL1 or selectable markers such as genes encoding hygromycin resistance can also be used in the method.

Example 4 Analysis of Wheat Transformants

Transformation was determined by one or more of the following methods: PCR analysis for one or more of the transgenes. PCR analysis was performed on genomic DNA extracted from 1-2 cm² of fresh leaf material using the mini-prep method described by Stacey and Isaac (1994). PCR reactions were performed, for example, using the primers SBEIIa-For: 5′-CCCGCTGCTTTCGCTCATTTTG-3′ [SEQ ID NO. 4] and SBEIIa-Rev: 5′-GACTACCGGAGCTCCCACCTTC-3′ [SEQ ID NO. 5] designed to amplify a fragment (462 bp) from the SBEIIa gene, or SBEIIb-DupFor 5′-AGATGTGAATGGCTGCTTGCTG-3′ [SEQ ID NO. 6] and SBEIIb-DupRev 5′-CAGGTCGACCATATGGGAGAGC-3′ [SEQ ID NO. 7] for SBEIIb (505 bp). Reaction conditions were as follows: “hot start” (94° C., 3 min) followed by 30 cycles of denaturation (95° C., 30 sec), annealing (55° C., 30 sec), extension (73° C., 2 min) followed by 1 cycle at 73° C. (5 min).

Southern blot hybridization analysis was performed on DNA from a larger scale (9 ml) extraction from lyophilized ground tissue (Stacey and Isaac, 1994). DNA samples were adjusted to 0.2 mg/ml and digested with restriction enzymes such as HindIII, EcoRI and KpnI. Restriction enzyme digestion, gel electrophoresis and vacuum blotting were carried out as described by Stacey and Isaac (1994). Digoxygenin-labelled probes including the intron 3 region of the ds-SBEII constructs were produced by PCR according to the method of McCreery and Helentjaris (1994). Hybridization of the probes to the Southern blot and detection by chemiluminescence were performed according to the method of McCreery and Helentjaris (1994).

The results of the PCR analyses are summarized in Table 2. Plants that were positive for the transgenes as demonstrated by PCR included 27 independent transformation events for ds-SBEIIa and 61 independent events for ds-SBEIIb.

TABLE 2 Transformation of wheat with SBEIIa and SBEIIb RNA duplex constructs. Experiment No. of embryos No. of lines PCR positive No. inoculated regenerated lines ds-SBEIIa construct 44 242 1 1 50 169 3 3 52 158 3 3 58 163 2 2 61 195 1 1 72 185 1 0 83 241 1 1 84 242 1 1 85 153 5 5 109  262 13 10 Total 2010 31 27 ds-SBEIIb construct 48 291 1 1 51 166 1 0 53 194 1 0 55 261 1 1 59 253 1 0 60 175 4 2 62 199 1 0 70 152 1 0 73 238 2 2 75 151 2 2 76 150 1 0 77 150 2 2 81 134 1 1 87 230 5 3 92 233 8 5 110  240 29 16 Total 3217 61 35

Example 5 Analysis of Grain from Plants Transformed with Duplex-RNA Constructs

Starch Granule Morphology.

The morphology of starch granules from mature T1 seed obtained from the T0 transformed wheat plants was observed by light microscopy. Ten individual grains from each of 25 T0 plants independently transformed with ds-SBEIIa and 12 plants independently transformed with ds-SBEIIb were analysed. Each endosperm was gently crushed to release the starch granules, which were dispersed in water and visualized under a light microscope. Of the 25 ds-SBEIIa lines analysed, 12 had grains with distorted granules although the visual observation revealed varying levels of distortion in different seeds. In contrast, none of the 12 ds-SBEIIb lines showed significant starch granule distortion in the endosperm when observed under light microscopy.

Observing the starch granules under polarized light revealed that there was a significant reduction in birefringence for distorted granules for the ds-SBEIIa grain. Loss of birefringence was observed for 94% of the granules in seeds from the line 50.1b, correlating with their distorted phenotype, while normal granules from another seed of the same line showed full birefringence. The seed with normal granules is presumed to be a segregant lacking the transgene and therefore phenotypically normal.

Light microscopy results were confirmed by scanning electron microscopy (SEM) of the starch granules. To do this, purified starch is sputtered with gold and scanned at 15 kV at room temperature.

Grain Weight

Individual grains from ds-SBEIIa transformed plants, grown under equivalent conditions in the greenhouse, were weighed (Table 3). Grains having severely distorted granules from plants 50.1b, 58.2a, 61.2a and 109 were not significantly reduced in average weight compared to grains of wild-type plants grown under the same conditions. Therefore, starch production did not appear to be substantially reduced even in the seeds with highly distorted starch granules. This data also suggests that the yield of field-grown wheat with reduced SBEIIa activity in the endosperm is about normal.

TABLE 3 Grain weight of T1 seeds from the ds-SBEIIa transgenic wheat lines Transgenic Seed Seed weight Starch granule Line No (mg) morphology* 50.1b 1 16.9 + 2 49.8 + 3 46.9 − 4 50.0 − 5 45.4 − 6 42.6 − 7 39.9 +/− 8 41.0 + 9 39.5 − 10 37.0 +/− 58.2a 1 44.0 − 2 37.4 + 3 48.8 − 4 43.2 + 5 46.2 − 6 42.1 + 7 43.5 +/− 8 45.7 − 9 38.8 − 10 38.1 +/− 61.2a 1 50.7 + 2 49.0 +/− 3 49.8 − 4 47.0 − 5 48.6 − 6 46.2 − 7 42.2 + 8 50.4 − 9 39.7 − 10 46.3 − 109.7b 1 40.1 − 2 34.6 − 3 43.7 − 4 38.8 − 5 33.8 +/− 6 31.1 +/− 7 35.9 + 8 44.3 +/− 9 37.7 − 10 41.4 − + normal starch granules, − severely distorted granules, +/− mild distortion of granules

Analysis of SBEIIa and SBEIIB Proteins in T2 Transgenic Wheat Endosperm.

Seed (T2) from 13 ds-SBEIIa transformed T1 plants, representing 5 independently transformed lines, and from 9 ds-SBEIIa transformed plants, representing 3 independently transformed lines, were analysed for SBEIIa and SBEIIb protein expression in endosperm by non denaturing PAGE and Western blotting. The ds-SBEIIa plants were all from lines having abnormal starch granule morphology, while the ds-SBEIIa SBEIIb lines all had normal granule morphology, as described above. The antibody used for detection of SBEIIa was 3KLH, from rabbits, which had been raised against the synthetic peptide having the amino acid sequence AASPGKVLVPDESDDLGC [SEQ ID NO: 8], corresponding to the sequence from the N-terminus of mature SBEIIa, and was diluted 1:5000 for use. The antibody used for detection of SBEIIb was R6, raised against the synthetic peptide having the amino acid sequence AGGPSGEVMIGC [SEQ ID NO. 9], corresponding to the deduced sequence from the N-terminus of mature SBEIIb and diluted 1:6000 before use. The secondary antibody used was GAR-Horseradish Peroxidase conjugate (1:3000 dilution). Immunoreactive bands were revealed using an Amersham ECL-detection system.

Endosperms from each of seven developing grains (15 days post anthesis) from each of the 22 T1 plants were analysed as it was expected that some of the plants would be heterozygous for the transgene. Twelve of the 13 ds-SBEIIa plants produced T2 progeny showing reduced levels of SBEIIa protein in the endosperm. All seven seeds from one line (50.3×0.9) appeared to lack SBEIIa entirely, while all seven seeds from four other plants showed obviously reduced expression of SBEIIa. These could represent lines that are homozygous for the transgene. Seven lines were segregating for the absence of SBEIIa or reduced levels of SBEIIa, or in some cases no apparent reduction of the protein, and these lines probably represent heterozygotes for the transgene. The thirteenth line (50.3×0.6) was homozygous for wild type expression.

Of the nine ds-SBEIIb transgenic lines tested, three (10.16b.2, 110.16b.5 and 110.16b.19) uniformly showed no SBEIIb expression in each of seven progeny seeds, while two were uniform for wild type expression and the remaining four were segregating for no expression, reduced expression or wild-type. Embryos from the seeds may be grown (embryo rescue) to produce T2 plants and T3 seed which are screened by PCR and protein expression analysis to confirm the genetic status of the T2 seed with respect to the transgene.

These data indicate that the duplex-RNA constructs were effective in reducing the expression of the SBEIIa and SBEIIB genes in endosperm of wheat. The data also indicate that reduction of SBEIIb expression alone did not substantially alter starch granule morphology.

The expression of the SBEIIb gene in transgenic seeds containing the ds-SBEIIa transgene and lacking SBEIIa protein, and the expression of the SBEIIa gene in seeds containing the ds-SBEIIb were also analyzed by the Western blot method. Unexpectedly, transgenic seeds comprising ds-SBEIIa were much reduced for SBEIIb. However, the converse effect was not observed in seeds transgenic for ds-SBEIIb. The SBEIIa expression was unaltered in the seeds in which SBEIIb was completely silenced by ds-SBEIIb. It is possible that expression of SBEIIb was suppressed by the ds-SBEIIa construct due to sequence homology between the genes in the region used for the duplex construct, it is also possible that the activity of SBEIIb was reduced by the ds-SBEIIa transgene by some other mechanism.

The expression levels of the SBEIIa and SBEIIb genes can also be specifically determined at the mRNA levels through standard techniques such as Northern hybridisation or RT-PCR methods, for example by using probes from non conserved regions or primer pairs which hybridize to unique sites in one of the genes but not the other, for example in the 3′ untranslated regions. Such regions or sites can readily be identified by comparison of the two gene sequences.

Example 6 Starch Analysis of Transformed Wheat

Amylose and Amylopectin Levels in Transgenic Wheat Grain.

The amylose content of starches from six pooled T1 seed samples was determined as described in Example 1. The pooled seed samples were obtained from the transgenic wheat lines as follows:

Pool 1—seed that had distorted starch granules from the ds-SBEIIa transgenic line 85.2c

Pool 2—seed that had normal granules from the ds-SBEIIa transgenic line 85.1a

Pool 3—seed that had normal granules from the ds-SBEIIb transgenic line 110.18a

Pool 4—seed that had distorted granules from the ds-SBEIIa transgenic lines 58.1a, 58.2a and 61.2a, pooled together

Pool 5—seed that had normal granules from the ds-SBEIIa transgenic line 83.1b

Pool 6—seed that had normal granules from the ds-SBEIIb transgenic line 75.3x.

Each analysis was done using four replicates of the starch samples. The regression equation used to convert the absorbance to amylose content for these analyses was Y=57.548x−8.793, where Y was the amylose content (%) and x was the absorbance. The results are given in the Table below. The presence of distorted starch granules was clearly associated with increased relative amylose contents. Starches from grains with distorted granules from the ds-SBEIIa transgenic lines (pools 1 and 4) had relative amylose contents of greater than 50% while the other starch pools, derived from grain with normal starch granules, had amylose contents in the range 21-26%. This included starch from line IIb 110.18a which had reduced expression of SBEIIb, which suggested that inactivation of SBEIIb alone in wheat did not substantially increase amylose levels in grain starch.

TABLE 4 Amylose content estimated by iodometric method of the transgenic wheat lines Starch Transgenic Amylose content (%) sample line Replication 1 Replication 2 Replication 3 Mean Pool 1 85.2c 65.7 54.2 53.2 57.7 Pool 2 85.1a 23.7 22.5 26.7 24.3 Pool 3 110.18a 22.3 21.0 21.5 21.6 Pool 4 58.1, 58.2a, 53.9 52.8 58.5 55.1 61.2a Pool 5 83.1b 26.5 25.3 24.8 25.6 Pool 6 75.3x 24.3 20.6 19.5 21.5

A second set of analyses was done by the iodometric method using a sample from Pool 4 and starch from wheat that was defective in SSII (Yamamori et al. 2000) and from barley line M292 which was mutant in SSIIa. The amylose content determined for starch from Pool 4 wheat seeds (ds-SBEIIa transgenic lines) was considerably higher than that of starch from the SSII mutants of wheat and barley.

This implied that the amylopectin content in the starch of these grains was considerably reduced, from about 75% in wild-type to less than 50% or even less than 20%.

Lines containing both ds-SBEIIa and ds-SBEIIb transgenes were generated by crossing the transgenic plants described above. Relative amylose contents in the grain starch of such progeny were elevated to the same extent compared to starch from plants containing only ds-SBEIIa, in the range of 75 or 80% as measured by Sepharose column methods (Example 8), when the ds-SBEIIa gene was introduced into the F1 plants from the female parent and the ds-SBEIIb gene from the male parent. Lower levels of amylose (55-60%) were observed in F1 progeny from the reciprocal cross. The difference could be due to the triploid nature of the endosperm which contains two copies of the maternal genome and one copy of the paternal genome. This indicated that the copy number of the ds-SBEIIa gene influenced the extent of the elevation in amylose levels, and was consistent with higher amylose levels in homozygotes than heterozygotes.

Discussion

There are three known mechanisms for increasing amylose content in plants: i) to increase GBSS activity, for example, over-expression of GBSS has recently been reported to yield a rice starch with increased amylose content (Itoh et. al., 2003); ii) to decrease amylopectin synthesis by suppression of the activity of starch synthases and isoamylases leading to a net increase in amylose content, for example, amylose contents of 35-45% have been in reported in maize sugary-2, sul and du-1 (Gao et. al., 1998) and wheat Sgp-1 (Yamamori et al., 2000) mutants, or greater than 70% amylose in a barley variety lacking SSIIa activity (Morell et al., 2003). As shown herein, the third mechanism for increasing amylose content was to suppress the activity of starch branching enzymes, with reduction in SBEIIa and SBEIIb in wheat resulting in starch with an amylose content of >70%, with concomitant changes in starch granule morphology, starch composition, and starch fine structure. This result contrasted with previous findings in maize (Garwood et al., 1976) and rice (Mizuno et al 1993) where reduction in SBEIIb was required for high amylose starch. The results with the hp-SBEIIa construct described above demonstrated that suppression of starch branching enzyme activity in the grain, including at least SBEIIa, provided a high amylose phenotype.

Example 7 Mutation of SBEIIA Gene in Wheat

Mutation of the SBEIIa gene in wheat leading to reduced activity of SBEIIa can be achieved through mutagenesis, for example either gamma ray irradiation or chemical mutagenesis using agents such as ethyl methane sulfonate (EMS). For gamma ray induced mutation, seeds may be irradiated at a dose of 20-50 kR from a ⁶⁰Co source (Zikiryaeva and Kasimov, 1972). EMS mutagenesis may be performed by treating the seeds with EMS (0.03%, v/v) as per Mullins et al., (1999). In a B+D double null background, mutant grains may be identified on the basis of increased amylose content or altered starch grain morphology and confirmed by the methods described above. Mutants in SBEIIa that retain SBEIIb activity can be re-mutagenized and the progeny screened for loss of SBEIIb activity in addition to SBEIIa, or the SBEIIa mutant can be crossed with an SBEIIb mutant to combine the mutations and produce a non-transgenic variety of wheat substantially lacking SBEII activity in the endosperm.

In an attempt to identify a wheat line having a mutation in an SBEIIa or SBEIIb gene, 2400 hexaploid wheat accessions were screened for null mutations of SBEIIb in the A, B or D genomes. The primers AR2b19cF/AR2b23cR were used in PCR reactions on genomic DNA samples of wheat plants of each line, followed by digestion of the amplification products with RsaI and gel electrophoresis. This marker amplified the intron 3 region (nucleotide positions 2085 to 2336 in wheat SBEIIb gene, FIG. 2) and was specific for SBEIIb. This screening had resulted in the identification of three D genome SBEII-null mutants and two B genome SBEII-null mutants as described in the Examples above. No mutant lines which lacked the A genome band corresponding to SBEIIB were detected. This suggested that wheat lines comprising chromosome 2A with a mutant SBEIIb gene do not occur naturally.

A gamma ray (⁶⁰Co source) induced mutant wheat population generated by Tony Prior and Rohit Mago (CSIRO) was used to screen for induced mutations in wheat SBEII. The wheat population was generated from the F2 progeny of a cross, Gabo 1BL.1RS x Veery 3. A total of 2694 mutant seeds from this population were screened as described above in PCR reactions with the primers AR2b19cF and AR2b23cR. Two seeds, designated MLT2B8 and MLT2D1, that came from one plant, were identified that lacked the SBEIIb A genome allele. No seeds in the population were identified to contain null mutations of SBEIIb in the B or D genomes.

Since the SBEIIa and SBEIIb genes were closely linked in wheat on the long arm of chromosome 2, DNA from seeds was tested for the presence or absence of the A genome SBEIIa gene with PCR reactions using the primers Sr913F/E6R. These primers amplify the intron 5 region of wSBEII-D1 (nucleotide positions 2959 to 3189, FIG. 1 [SEQ ID No. 1]). After amplification, the products were electrophoresed on a 5% sequencing gel (ABI Prism DNA sequencer). Fluorescently labeled products were analysed using the software Genescan. The scan profiles showed that the amplification products for both of the mutant seeds MLT2B8 and MLT2D1 lacked the product corresponding to the A genome SBEIIa gene, indicating that both seeds had null alleles for the A genome SBEIIa in addition to SBEIIb.

The null mutations in these seeds were further confirmed by using an A genome specific marker for SBEIIa, ARIIaAF (5′-GCAAAAGCCAGATCATAAATTTAGAGC-3′) [SEQ ID NO. 10] and ARIIaAR (5′-CTTCCAATTCATTGTTAATGGTCACAC-3′) [SEQ ID NO. 11] that amplify only the product from A genome SBEIIa gene (nucleotide positions 3024 to 3131 of wSBE II-DA1, FIG. 1). While this pair of primers amplified a 110 bp product from plant material from the variety Chinese Spring, this product was clearly missing in the two putative mutant seeds. This was the same as for the negative control dt2AS, which is a chromosome engineered line of Chinese Spring that is missing the long arm of chromosome 2A. Since the SBEIIa and SBEIIb genes are located on the long arm of chromosome 2, this line lacks the A genome allele of both these genes and hence could be used as a negative control.

Five lines having mutation in both the B and D genome SBEIIa and SBEIIb genes had been generated. Of these, lines such as BD 219 and BD 636 may be crossed to an A null mutant line and a doubled haploid population may be generated from the F1 seeds of these crosses to provide homozygous triple null mutant plants. Such triple null mutant plants should occur in doubled haploid populations at a frequency of 1 in 8. The A genome null mutations can be combined with either the B genome mutations or the D genome mutations by similar crosses. In further crosses, any of the null alleles can be introduced into any suitable genetic background for agronomic or other traits.

Crosses may also be performed to produce durum wheat (such as, for example, variety Wollaroi) having mutations in the A genome or B genome SBEIIa and SBEIIb, or both A and B genome mutations for both genes to produce durum wheat lacking SBEII activity.

Such durum wheat is non-transgenic and has a high amylose phenotype which provides health benefits similar to that of high amylose hexaploid wheat.

Example 8 Confirmation of the High Amylose Content in Grain by Sepharose 2B Column Separation Methods

The amylose content of starch in the grain of transgenic wheat plants containing SBEIIa/SBEIIb inhibitory genetic constructs was determined by a Sepharose column separation method. In this method, starch molecules were separated on the column based on their molecular weight. The separated fractions were then assayed using the Starch Assay Kit (Sigma) according to the suppliers instructions.

Approximately 10 mg of starch was dissolved in 3.0 ml of 1N NaOH (de-gassed) by incubation at 37° C. for 30 min. The starch solution was centrifuged for 15 min to spin down the undissolved components. The supernatant was loaded on to a Sepharose CL2B column at a pump speed of 1 ml/min. The column was run using 10 mM NaOH as buffer and fifty fractions of 2.5 ml each were collected. The pH of fractions 9 to 50 was adjusted to 4.5 with 35 μl of 1 M HCl. An aliquot (250 μl) of each sample was transferred into a tube followed by the addition of 250 μl of Starch reagent (Starch assay kit, Sigma). The controls included: a starch assay reagent blank containing only starch reagent (250 μl) and water (250 μl), a glucose assay reagent blank containing only 500 μl water, a sample blank containing only 250 μl starch sample and 250 μl water and a sample test containing only 250 μl starch reagent and 250 μl starch sample. The samples and the controls were incubated at 60° C. for 60 min, and then 200 μl of each transferred to a new tube followed by addition of 1 ml of glucose reagent (starch assay kit, Sigma) and incubation at 37° C. for 30 min. The absorbance at 340 nm was used to determine the quantity of starch (mg) in each fraction according to the instructions supplied with the kit. The chromatogram of starch samples revealed two peaks eluted from the Sepharose column. The amylose content (second peak) of each sample was calculated as a percentage of the total amount of starch within both of the peaks.

Using this method, the amylose content of the ds-SBEIIa transgenic line Acc. 144087, which was shown to be homozygous for the transgene, was calculated to be 78% and that of a ds-SBEIIb transgenic line Acc 144008 (homozygous transgenic line from the event IIb 110.16b) was estimated to be 23%. In comparison, the iodometric method gave amylose contents for these lines of 88.47% and 27.29%, respectively.

Functional properties such as gelatinization temperature, paste viscosity and starch swelling volume are analysed by Differential Scanning Calorimetry (DSC), Rapid Visco Analyser (RVA) and starch swelling power test, respectively. The structure of these starches is analysed by X-ray crystallography and particle size analysis.

TABLE 5 Amylose content of wheat transgenic lines estimated by iodometric method Amylose content Line Target enzyme Event No. (%) NB1 Non transformed — 31.8 144008 SBE IIb IIb 110.16b 27.3 144087 SBE IIa IIa 85.3a 88.5 144025 SBE IIa IIa 50.1b 75.8 LSD — — 7.7

Example 9 Chain Length Distribution Analysis

The chain length distribution of starch samples was determined by fluorophore assisted carbohydrate electrophoresis (FACE) after isoamylase de-branching of the starch. The percentages of chain lengths from DP 6-11, DP 12-30 and DP 31-60 in starch from the transgenic seed compared to non-transgenic controls are presented in Table 6.

TABLE 6 Chain length distribution of isoamylase debranched starches from wheat transgenic lines. Targeted Line gene Event No DP4-12 DP13-24 DP24-36 >36 NB1 Non- — 57.39 37.38 3.83 1.40 trans- formed control 144087 SBEIIa IIa 85.3a 47.40 42.27 6.16 4.17 144025 SBEIIa IIa 50.1b 49.99 44.40 5.60 — 144008 SBEIIb IIb 57.98 37.65 4.37 — 110.16b

There was a significantly lower proportion of chain lengths of DP 4-12 in starch from ds-SBEIIa transgenic seed compared to starch from untransformed seed or ds-SBEIIb transgenic seed. The proportion of chain lengths of >DP 13 was higher in ds-SBEIIa transgenic seed compared to the others. These results suggest the possibility that SBEIIa is selectively involved in the synthesis of shorter chains of DP 4-12 in wheat starch. In starch from the SSIIa mutant, however, there was an increase in the proportion of shorter chain lengths in the amylose.

Example 10 Properties of Starch from SBEIIA-Modified Wheat

Physical properties of starch from ds-SBEIIa and ds-SBEIIb transgenic lines including the gelatinisation temperature were analysed using a Perkin Elmer Diamond differential scanning calorimeter. Approximately 20 mg of each starch was mixed with water at a ratio of 1:2 i.e. to a moisture content of 66.7%, and sealed in a DSC pan. A heating rate of 10° C. per minute was used to heat the test and reference samples from 0 to 150° C. Data were analysed using the software available with the instrument.

Two endotherm peaks were observed in the thermogram DSC trace for each starch. The first peak represented the breakdown of crystalline structure during gelatinization of starch. The second peak represented the amylose-lipid dissociation endotherm. The gelatinization peak temperature of starch from ds-SBEIIa transgenic lines showed an increase of approximately 7-10° C. compared to the peak temperature for a non-transformed control starch, and approximately 3 to 7° C. increased compared to starch from a ds-SBEIIb transgenic line.

TABLE 7 Thermal properties of transgenic wheat starch measured by differential scanning calorimeter (DSC). Peak 2 (Amylose-lipid Enzyme Peak 1 (Gelatinisation) dissociation) Lines targeted Onset Peak End Area ΔH Onset Peak End ΔH 008 SBE IIb 58.8 63.7 70.8 234.8 4.5 93.2 103.5 110.3 0.7 012 SBE IIb 59.0 64.1 70.8 262.6 4.3 94.5 103.1 109.7 0.6 121 SBE IIa 53.7 67.5 86.9 156.4 2.6 92.4 102.9 108.9 0.7 087 SBE IIa 53.1 71.9 85.9 142.6 2.4 95.7 102.7 108.9 0.7 114 SBE IIa 53.0 68.1 88.0 125.2 2.1 92.8 102.5 109.6 0.8 109c Control* 55.9 60.7 68.8 234.3 3.9 97.2 104.6 109.9 0.4

A marked increase in the end temperature of gelatinization (first peak) of approximately 16-19° C. was observed in these lines compared to both non-transformed control and ds-SBEIIb transgenic lines. The temperature of onset of gelatinization appeared to be earlier in ds-SBEIIa transgenic lines than the control or ds-SBEIIb transgenic lines. Ng et al., 1997 reported a gelatinization onset temperature of amylose extender (ae) maize starch similar to that of normal maize starch, but a significant increase in the peak gelatinization temperature in ae starch compared to normal starch. The gelatinization enthalpy of starch from ds-SBEIIa transgenic lines was significantly lower than that of both the control and ds-SBEIIb lines. This seems to be reflecting the significantly lower gelatinization peak area which represents the reduced amount of amylopectin in ds-SBEIIa transgenic lines. No significant alteration was observed in the amylose-lipid dissociation peak in any of the transgenic lines. We have therefore obtained starch with this novel set of properties.

The wheat high amylose starches as described above had structural and functional properties that were similar, but not identical, to high amylose maize starch. Two key differences were noted. Firstly, the increase in peak gelatinisation temperature for high amylose wheat was not as large as the difference observed previously for maize amylose extender starch compared to standard maize. Secondly, there was a reduction in starch content of approximately 30% in amylose extender maize lines (Singletary et al., 1997), however, a suppression of starch content of only 9% was observed for high amylose wheat. Additional increases in amylose content in wheat may be obtained by transferring the hp-SBEIIa and hp-SBEIIb constructs into a SBEI-null background.

Example 11 Animal Trial

Care of Animals.

Young adult, male Sprague Dawley rats were used. They were purchased from the University of Adelaide Animal Resource Facility and housed in groups in standard wire-bottomed cages at the Animal Services Unit of CSIRO Health Sciences and Nutrition in a room of controlled temperature (22±1° C.) and lighting (lights on at 0800-2000 h).

Diets and Feeding

After arrival the rats were adapted to a nonpurified commercial diet for 7 days. They were then weighed and allocated randomly to two dietary treatment groups of six rats each, of equal mean live weight, and transferred to a purified diet. The composition of the basal diet, which was based on AIN 93G (American Institute of Nutrition, 1993) specifications and prepared from standard ingredients, is shown in Table 8. The diets were balanced for macronutrients and comprised 200 g of protein/kg, 550 g of carbohydrate/kg (as 450 g of starch and 100 g of sucrose), 70 g of fat/kg and 90 g of non-starch polysaccharide (NSP) per kg. Processed wheat bran, safflower oil and casein were used to obtain the desired macronutrient profile. Low amylose maize starch was used to ensure uniform starch content (45 g/100 g) for the two diets. The high-amylose wheat diet contained 576 g/kg of the novel (high amylose) wheat as wholemeal flour. Other treatment diets contained between 32% and 48% of the respective wholemeal flour (low-amylose wheat) or starch (low amylose or high amylose maize). Diets may be prepared by blending the various ingredients with a small quantity of water using a planetary mixer. The mixture may then be pelleted (for example to a diameter of 8 mm and a length of 1-2 cm) by extrusion, dried for 16 h at 40° C., and placed in sealed containers and stored at 4° C. Alternatively, as carried out in this experiment, diets were prepared as a powder and freely available, as was drinking water.

TABLE 8 Formulation of the low and high amylose wheat diets Low amylose High amylose wheat wheat Ingredient (g/kg of diet) Casein 113 72 Sucrose 116 120 Safflower oil 44 38 Wheat bran 121 65 Low amylose wheat flour 481 High amylose wheat flour 576 Maize starch* 83 86 Vitamin premix 8 9 Mineral premix 29 30 Choline 2 2 L-Cysteine 2 2 *Conventional (low-amylose) starch (3401C) (Penford Australia Pty Ltd, Lane Cove NSW). ^(†) Pharmamix P169 (Propharma Australia Pty Ltd, Dandenong, Victoria) which contained, per kg mix, 1.5 g retinyl acetate, 25 mg cholecalciferol, 20 g α-tocopherol, 2 g riboflavin, 7.5 mg cyanocobalamin, 5.6 g Ca pantothenate, 50 mg biotin, 10 g nicotinamide, 1 g menadione, 50 g FeSO₄.7H₂O, 10 g MnO₂, 50 g ZnO, 5 g CuSO₄.7H₂O, 0.25 g CoSO₄, 0.5 g KI, 0.1 g Na₂SeO₄, and 31 g antioxidant(Oxicap E2; Novus Nutrition, Melbourne Australia).

Rats had unrestricted access to treatment diets and drinking water for 13 days. During the last 9 days, the animals were kept in individual metabolism cages to allow accurate estimation of feed and water intake and total collection of faeces which were retained for analysis. Rats were observed daily and weighed weekly. Diet consumption of rats when housed individually in metabolism cages was recorded daily, as was the weight of faeces.

Feed Intake and Body Weight Gain

Initial body weight did not differ between the groups (overall mean of 193 g; n=12, pooled SE=3). Diets were well accepted and supported rates of food consumption and weight gain (average 6.5 g/d) that were appropriate for rats of this age. There was no effect of dietary treatment on final body weight with a mean of 278 g (SE=7, n=6) and 282 g (SE=6, n=6) for the low and high amylose wheat, respectively. Daily food intake averaged 20 g/d for each of the two groups (P>0.05) during the metabolism cage phase of the study.

Large Bowel Tissue and Digesta Weights

Rats were anaesthetised with halothane, the abdominal cavity opened and the caecal and colonic contents collected, weighed and stored at −20° C. until analysis. The moisture content of caecal digesta was determined by freeze-drying a portion to constant weight, and weighing the portion before and after drying. Data below from the trial are shown as the mean±standard error (SE) for 6 observations per group. They were analysed by t-test and a value of P<0.05 was taken as the criterion of significance.

Large bowel tissue weight was generally greater in rats fed the high amylose wheat but only in the caecum did the effect near significance (P<0.07). In that viscus, the weights were 0.92 g (SE=0.18, n=6) and 1.23 g (SE=0.39, n=6), for the low and high amylose wheats respectively. Thus, the high amylose diet tended to increase tissue mass. The average wet weight of digesta was higher in rats fed the new wheat, tending to be greater in each large intestinal compartment, but the effect was statistically significant only in the caecum where it was more than 2.1-fold higher than in rats fed the low amylose wheat diet (Table 9). Not only did the consumption of the high amylose diet usually result in wetter luminal contents, the dry weight of digesta was still also considerably greater for the high amylose treatment.

TABLE 9 Large bowel digesta weight (g) of rats consuming low or high amylose wheat diets Colon Diet Caecum Proximal Distal Low amylose wheat 1.47 (0.12)^(a) 0.29 (0.12) 0.83 (0.17) High amylose wheat 3.14 (0.34)^(a) 0.48 (0.09) 1.10 (0.08) All values are the mean and standard error (in parentheses) for six animals. Values in a column with like superscript letters are significantly different: ^(a)P < 0.01.

Large Bowel SCFA and pH

Digesta and faecal samples were diluted with a specified volume of internal standard (heptanoic acid) for analysis of SCFA and mixed thoroughly for determination of pH using a standard glass electrode. The slurries were then stored frozen to await further analyses. For analysis of total and major individual SCFA, slurries were thawed, centrifuged and concentrated by low temperature vacuum microdistillation for quantification by gas-liquid chromatography (GLC).

Data for the caecum are shown in Tables 10 and 11. The high amylose wheat produced a lower pH value in caecal contents (Table 10). While there were no significant differences in the concentrations of either total or individual short-chain fatty acids (SCFA, Table 10), caecal digesta pools for the total and individual acids were all significantly higher in rats fed the high amylose wheat diet than in controls (Table 11). Faecal total SCFA excretion was also significantly higher (P<0.02) in rats fed the high amylose wheat with a mean value of 46.1 (SE=5) μmol/d compared with 24.7 (SE=5) μmol/d by rats fed the standard wheat.

TABLE 10 Caecal digesta pH and short chain fatty acid concentrations of rats consuming low and high amylose wheat diets Short chain fatty acid concentration (mmol/Kg) Diet pH Acetate Propionate Butyrate Total Low 6.23 (0.05)^(a) 38.6 (1.9) 11.9 (1.7) 25.8 (3.3) 79.6 (3.1) amylose wheat High 5.90 (0.14)^(a) 43.6 (7.8) 15.8 (3.1) 23.0 (2.5) 84.1 (8.6) amylose wheat All values are the mean and SE (in parentheses) for six animals. Values in any column with like superscript letters are significantly diferent: ^(a)P < 0.05.

TABLE 11 Caecal short chain fatty acid pools of rats consuming low and high amylose wheat diets Short chain fatty acid pools (μmol) Diet Acetate Propionate Butyrate Total Low amylose wheat  44 (4)^(c) 14 (2)^(b) 31 (6)^(a)  88 (10)^(c) High amylose wheat 106 (18)^(c) 38 (7)^(b) 57 (8)^(a) 202 (25)^(c) All values are the mean and SE (in parentheses) for six animals. Values in any column with like superscript letters are significantly different: ^(a)P < 0.05; ^(b)P < 0.02; ^(c)P < 0.01.

This experiment showed that modified wheat containing high amylose starch induced positive changes in the gastrointestinal tract of a mammalian animal. These changes were consistent with, and could be explained by, the presence of increased levels of resistant starch (RS) in the modified wheat. A key outcome was to confirm that the increased level of amylose translated to desired physiological attributes. Therefore, the modified wheat has the potential to deliver significant health benefits to large numbers of consumers through their diet.

It was observed that food intakes and body weight gain did not differ between the low and high-amylose wheat treatment groups and there was no evidence for any adverse impact on the growth and performance of the animals fed the transgenic high amylose wheat. This was in contrast to a previous report in rats fed a transgenic raw potato starch containing a known toxin, the lectin Galanthus nivalis agglutinin (GNA) where a loss of body weight occurred (Ewen and Pusztai, 1999).

Limitations in the quantities of grain meant that the trial described above had to be carried out in rats for a relatively short period of time. Nevertheless, the data show conclusively that indices of large bowel fermentation were all significantly higher in rats fed the high amylose wheat compared with those fed the standard wheat, consistent with an elevated level of RS. Thus large bowel digesta wet weight and SCFA pools and faecal SCFA excretion were all approximately 100% larger in rats fed the modified wheat compared with those fed the control diet. pH values were also significantly lower, again consistent with greater fermentation. That these differences were due to starch, and not NSP, was ensured by balancing the fibre content of the diets. This is of some interest in view of the apparent importance of butyrate in promoting large bowel function Collectively the data support the potential of the high amylose wheat to produce foods high in RS and with a low GI. The data demonstrate the health potential of high amylose wheats, especially in processed foods, as an important additional mechanism to deliver significant health benefits to large numbers of consumers through their diet.

Example 12 Production of Breads

One of the most effective ways of delivering a grain such as high amylose wheat into the diet is through bread. To show that the high amylose wheat could readily be incorporated into breads and to examine the factors that allowed retention of bread making quality, samples of flour were produced, analysed and used in baking. Initially, only small quantities of the high amylose grain were available and therefore dough mixing and baking were carried out on a small scale (10-15 g). Such methods can readily be scaled up to commercial level when sufficient grain is available.

Methods:

Wheat grains were conditioned to 16.5% moisture content overnight and milled with either a Buhler laboratory scale mill at BR1 Ltd, Australia, or using a Quadromat Junior mill followed by sieving, to achieve a final particle size of 150 μm. The protein and moisture content of the samples was determined by infrared reflectance (NIR) according to AACC Method 39-11 (1999), or by the Dumas method and air-oven according to AACC Method 44-15A (AACC, 1999).

Micro Z-Arm Mixing

Optimum water absorption values of wheat flours were determined with the Micro Z-arm Mixer, using 4 g of test flour per mix (Gras et al 2001; Bekes et al 2002). Constant angular velocity (with shaft speeds for the fast and slow blades of 96 and 64 rpm, respectively) was used during all mixes. Mixing was carried out in triplicate, each for 20 minutes. Before adding water to the flour, the baseline was automatically recorded (30 sec) by mixing only the solid components. The water addition was carried out in one step using an automatic water pump. The following parameters were determined from the individual mixing experiments by taking the averages: WA %—Water Absorption was determined at 500 Brabender Unit (BU) dough consistency; Dough Development Time (DDT): time to peak resistance (sec).

Mixograins

To determine optimal dough mixing parameters with the modified wheat flour, samples with variable water absorption corresponding to water absorption determined by the Micro Z-arm mixer, were mixed in a 10 g CSIRO prototype Mixograph keeping the total dough mass constant. For each of the flour samples, the following parameters were recorded: MT—mixing time (sec); PR—Mixograph peak resistance (Arbitrary Units, AU); BWPR—band width at peak resistance (Arbitrary Units, AU); RBD—resistance breakdown (%); BWBD—bandwidth breakdown (%); TMBW—time to maximum bandwidth (s); and MBW—maximum bandwidth (Arbitrary Units, A.U.).

Micro Extension Testing

Dough extensibility parameters may be measured as follows: Doughs may be mixed to peak dough development in a 10 g prototype Mixograph. Extension tests at 1 cm/s may be carried out on a TA.XT2i texture analyser with a modified geometry Kieffer dough & gluten extensibility rig (Mann et al 2003). Dough samples for extension testing (˜1.0 g/test) may be moulded with a Kieffer moulder and rested at 30° C. and 90% RH for 45 min. before extension testing. The R_Max and Ext_Rmax may be determined from the data with the help of Exceed Expert software (Smewing, 1995; Mann, 2002).

The recipe used, based on the 14 g flour as 100% was as follows: flour 100%, salt 2%, dry yeast 1.5%, vegetable oil 2%, and improver (ascorbic acid 100 ppm, fungal amylase 15 ppm, xylanase 40 ppm, soy flour 0.3%, obtained from Goodman Fielder Pty Ltd, Australia) 1.5%. The water addition level was based on the micro Z-arm water absorption values that were adjusted for the full formula. Flour (14 g) and the other ingredients were mixed to peak dough development time in a 35 g Mixograph. The moulding and panning were carried out in a two staged proofing steps at 40° C. at 85% RH. Baking was carried out in a Rotel oven for 15 min at 190° C. Loaf volume (determined by the seed (canola) displacement method) and weight measurements were taken after cooling on a rack for 2 hours. Net water loss was measured by weighing the loaves over time.

The flour or wholemeal may be blended with flour or wholemeal from non-modified wheats or other cereals such as barley to provide desired dough and bread-making or nutritional qualities. For example, flour from cvs Chara or Glenlea has a high dough strength while that from cv Janz has a medium dough strength. In particular, the levels of high and low molecular weight glutenin subunits in the flour is positively correlated with dough strength, and further influenced by the nature of the alleles present. In this example, the high amylose wheat flour was blended with flour from the control untransformed line, NB1.

Results.

The water absorption characteristics of the flours obtained from modified wheats were measured (FIG. 4). Blending of the high amylose flour with varying ratios of control flour showed that the high amylose wheat flour had higher water absorbance than the control flour, and this was positively correlated with the level of amylose in the starch—as seen by comparing 50.3x/6/(60.1% amylose) and 85.2c (81.0% amylose). This result may reflect the influence of the altered starch granule size and shape on water absorption characteristics, however, it is also probable that other changes in the high amylose grain such as altered non-starch polysaccharide content may affect water absorption.

The specific volumes for admixtures of high amylose and control flours, mixed in ratios from 0:100 to 100:0 was also determined, and the data are shown in FIG. 5. This result shows that the addition of high amylose wheat tended to reduce loaf volume. However, breads containing up to 50% high amylose wheat flour had very acceptable loaf volumes and could be used in standard white bread applications. Breads containing >50% high amylose wheat flour produced loaves have reduced loaf volumes and were suited for heavier style breads such as wholemeal or mixed grain breads. It was thought that further manipulation of improvers, gluten addition, and/or alteration to the genetic background of the wheat variety was likely ameliorate the observed reduction in loaf volume.

The optimal mixing time of doughs made from mixtures of high amylose and control wheat flour was measured (FIG. 6) and showed that mixing times were within a range considered acceptable for commercial bakery applications.

These studies showed that breads with commercial potential, including acceptable crumb structure, texture and appearance, were obtained using the high amylose wheat flour samples. Furthermore, high amylose wheats may be used in combination with preferred genetic background characteristics (e.g. preferred high and low molecular weight glutenins), the addition of improvers such as gluten, ascorbate or emulsifiers, or the use of differing bread-making styles (e.g. sponge and dough bread-making, sour dough, mixed grain, or wholemeal) to provide a range of products with particular utility and nutritional efficacy for improved bowel and metabolic health.

Example 13 In Vitro Measurements of Glycemic Index (GI) and Resistant Starch (RS) of Food Samples

The Glycemic Index (GI) of food samples including the bread made as described in Example 12 was measured in vitro as follows:

The food sample was homogenised thoroughly with a Zyliss blender. An amount of sample representing approximately 50 mg of carbohydrate was weighed into a 120 ml plastic sample container and 100 μl of carbonate buffer added without α-amylase. Approximately 15-20 seconds after the addition of carbonate buffer, 5 ml of Pepsin solution (65 mg of pepsin (Sigma) dissolved in 65 ml of HCl 0.02M, pH 2.0, made up on the day of use) was added, and the mixture incubated at 37° C. for 30 minutes in a reciprocating water bath at 70 rpm. Following incubation, the sample was neutralised with 5 ml of NaOH (0.02M) and 25 ml of acetate buffer 0.2M, pH 6 added. 5 ml of enzyme mixture containing 2 mg/mL of pancreatin (α-amylase, Sigma) and 28 U/mL of amyloglucosidase from Aspergillus niger (AMG, Sigma) dissolved in Na acetate buffer (sodium acetate buffer, 0.2 M, pH 6.0, containing 0.20 M calcium chloride and 0.49 mM magnesium chloride) was then added, and the mixture incubated for 2-5 minutes. 1 ml of solution was transferred from each flask into a 1.5 ml tube and centrifuged at 300 rpm for 10 minutes. The supernatant was transferred to a new tube and stored in a freezer. The remainder of each sample was covered with aluminium foil and the containers incubated at 37° C. for 5 hours in a water bath. A further 1 ml of solution was then collected from each flask, centrifuged and the supernatant transferred as carried out previously. This was also stored in a freezer until the absorbances could be read.

All samples were thawed to room temperature and centrifuged at 300 rpm for 10 minutes. Samples were diluted as necessary (1 in 10 dilution usually sufficient), 10 ul of supernatant transferred from each sample to 96-well microtitre plates in duplicate or triplicate. A standard curve for each microtitre plate was prepared using glucose (0 mg, 0.0625 mg, 0.125 mg, 0.25 mg, 0.5 mg and 1.0 mg). 200 ul of Glucose Trinder reagent (Thermotrace, Noble Park, Victoria) was added to each well and the plates incubated at room temperature for approximately 20 minutes. The absorbance of each sample was measured at 505 nm using a plate reader and the amount of glucose calculated with reference to the standard curve.

The level of Resistant Starch (RS) in food samples including the bread made as described in Example 12 was measured in vitro as follows. This method describes the sample preparation and in vitro digestion of starch in foods, as normally eaten. The method has two sections: firstly, starch in the food was hydrolysed under simulated physiological conditions; secondly, by-products were removed through washing and the residual starch determined after homogenization and drying of the sample. Starch quantitated at the end of the digestion treatment represented the resistant starch content of the food.

On day 1, the food samples were processed in a manner simulating consumption, for example by homogenising with a kitchen chopper to a consistency as would be achieved by chewing. After homogenising, an amount of food representing up to 500 mg of carbohydrate was weighed into a 125 mL Erlenmeyer flask. A carbonate buffer was prepared by dissolving 121 mg of NaHCO₃ and 157 mg of KCl in approximately 90 mL purified water, adding 159 μL of 1 M CaCl₂.6H₂O solution and 41 μL of 0.49 M MgCl₂.6H₂O, adjusting the pH to 7 to 7.1 with 0.32 M HCl, and adjusting the volume to 100 mL. This buffer was stored at 4° C. for up to five days. An artificial saliva solution containing 250 units of α-amylase (Sigma A-3176 Type VI-B from porcine pancreas) per mL of the carbonate buffer was prepared. An amount of the artificial saliva solution, approximately equal to the weight of food, was added to the flask. About 15-20 sec after adding the saliva, 5 mL of pepsin solution in HCl (1 mg/mL pepsin (Sigma) in 0.02 M HCl, pH 2.0, made up on day of use) was added to each flask. The mixing of the amylase and then pepsin mimicked a human chewing the food before swallowing it. The mixture was incubated at 37° C. for 30 min with shaking at 85 rpm. The mixture was then neutralised with 5 mL of 0.02M NaOH. 25 mL of acetate buffer (0.2 M, pH 6) and 5 mL of pancreatin enzyme mixture containing 2 mg/mL pancreatin (Sigma, porcine pancreas at 4×USP activity) and 28 U of amyloglucosidase (AMG, Sigma) from Aspergillus niger in acetate buffer, pH6, were added per flask. Each flask was capped with aluminium foil and incubated at 37° C. for 16 hours in a reciprocating water bath set to 85 rpm.

On day 2, the contents of each flask was transferred quantitatively to a 50 mL polypropylene tube and centrifuged at 2000×g for 10 min at room temperature. The supernatants were discarded and each pellet washed three times with 20 mL of water, gently vortexing the tube with each wash to break up the pellet, followed by centrifugation. 50 uL of the last water wash was tested with Glucose Trinder reagent for the absence of free glucose. Each pellet was then resuspended in approximately 6 mL of purified water and homogenised three times for 10 seconds using an Ultra Turrax TP18/10 with an S25N-8G dispersing tool. The contents were quantitatively transferred to a 25 mL volumetric flask and made to volume. The contents were mixed thoroughly and returned to the polypropylene tube. A 5 mL sample of each suspension was transferred to a 25 mL culture tube and immediately shell frozen in liquid nitrogen and freeze dried.

On day 3, total starch in each sample was measured using reagents supplied in the Megazyme Total Starch Procedure kit. Starch standards (Regular Maize Starch, Sigma S-5296) and an assay reagent blank were prepared. Samples, controls and reagent blanks were wet with 0.4 mL of 80% ethanol to aid dispersion, followed by vortexing. Immediately, 2 mL of DMSO was added and solutions mixed by vortexing. The tubes were placed in a boiling water bath for 5 min, and 3 mL of thermostable α-amylase (100 U/ml) in MOPS buffer (pH 7, containing 5 mM CaCl₂ and 0.02% sodium azide added immediately. Solutions were incubated in the boiling water bath for a further 12 min, with vortex mixing at 3 min intervals. Tubes were then placed in a 50° C. water bath and 4 mL of sodium acetate buffer (200 mM, pH 4.5, containing 0.02% sodium azide) and 0.1 mL of amyloglucosidase at 300 U/ml added. The mixtures were incubated at 50° C. for 30 min with gentle mixing at 10 min intervals. The volumes were made up to 25 mL in a volumetric flask and mixed well. Aliquots were centrifuged at 2000×g for 10 min. The amount of glucose in 50 μL of supernatant was determined with 1.0 mL of Glucose Trinder reagent and measuring the absorbance at 505 nm after incubation of the tubes at room temperature in the dark for a minimum of 18 min and a maximum of 45 min.

Results

The GI and RS content of breads made with the high amylose wheat flour (>30% amylose (w/w)) were determined. As controls, breads were also made from wheat lines obtained from a cross between varieties Sunco and an SGP-1 triple null mutant (Yamamori et al.). Doubled-haploid plants were obtained from progeny of the cross and grown to provide a population of homozygous lines segregating for the three SGP-1 mutant alleles. The presence of mutant alleles in each line was determined by gene specific (SSIIa gene) PCR reactions on isolated DNA from each line. Thus, the contribution of each of the null alleleles for the SSIIa gene on the A, B and D genomes could be assessed, singly and in each of the possible combinations. Grain from each of the lines was used for bread production by the small-scale method as described above. The results of the in vitro GI and RS measurements are shown in FIGS. 7 and 8.

The GI and RS were also measured for breads made from the high amylose wheat flour blended with control, low amylose flour, using 0%, 10%, 20%, 30%, 50%, 75% or 100% high amylose flour. The data are also presented in FIGS. 7 and 8. The levels of RS increased linearly with increasing amylose content, as the proportion of flour from the high amylose wheat increased. Breads made from flour comprising entirely transgenic high amylose wheat exhibited very high resistant starch levels, with transgenic line 85.2c having substantially higher levels of RS than line 50.3 (6.2 vs 4.5 g RS/100 g bread, respectively). Therefore, replacement of flour from control (low amylose) wheat with the high amylose wheat for production of the bread correlated positively with increased RS.

The levels of RS made with high amylose wheat starch were much higher than in commercially available bread (Wonderwhite) containing high amylose corn starch (“Hi-Maize”) used at 10% in the formulation, which had <1% RS. Furthermore, the maximum level of corn starch that can be incorporated in bread without affecting its quality is limited to about 10-12%. Therefore, the use of high amylose wheat in the production of breads provided significant advantages including the level of RS that could be achieved.

The rate of in vitro starch hydrolysis was reduced for the bread made with the modified wheat compared to the bread made with the wild-type wheat. The GI decreased only slightly while the percentage of high amylose wheat flour increased to 30%, but then decreased more rapidly as a greater proportion of high amylose flour was added. The greatest advantage in lowering the GI was seen for food made with at least 50% high amylose wheat flour. Breads made using the higher amylose line 85.2c had a slightly lower GI as measured in vitro than the bread made with line 50.3.

Discussion

The in vitro assays were useful in estimating the quantity of starch in a food product that would be digested or not digested in the small intestine. They yielded values that are thought to accurately and reliably predict the in vivo GI and RS content of foods. Importantly, foods were analysed ‘as consumed’ which is important considering that food processing methods may have a deleterious lowering effect on the level of RS. In the case of the modified wheat breads, the results demonstrated that physiological functionality (in particular high RS and low GI) had not been destroyed during cooking or storage, and presumably would be present at the point of consumption.

Most processed starchy foods contain very little RS. The breads made using wild-type wheat flour and a conventional formulation and baking process contained <1% RS. In comparison, breads baked using the same process and storage conditions but containing the modified high amylose wheats had levels of RS as much as 10-fold higher. Legumes, which are one of the few rich sources of RS in the human diet, contain levels of RS that are normally <5%. Therefore, consumption of the high amylose wheat bread in amounts normally consumed by adults (e.g. 200 g/d) would readily supply at least 5-12 g of RS. Thus, incorporation of the high amylose wheat into food products has the potential to make a considerable contribution to dietary RS intakes of developed nations, where average daily intakes of RS are estimated to be only about 5 g.

Starch that is resistant to small intestinal digestion enters the large bowel where, largely through its interaction with the microflora, it has a favourable influence on colonic physiology and function.

The rate at which starch is hydrolysed and absorbed in the small intestine determines to a large extent its metabolic properties. The GI ranks foods according to their postprandial glycemic response. Starchy foods that are rapidly digested (high GI) have adverse health consequences, including increased risk of diabetes, obesity and possibly certain cancers. Breads made from the modified wheat flours (transgenic) were shown to have a low GI (<55), particularly when the proportion of modified wheat flour comprised at least 50% of the flour component in the bread formulation. It was possible that components of the modified grains other than starch, such as for example non-starch polysaccharide (NSP) also contributed to the decrease in starch digestibility as measured in vitro. The data suggested that these products made from the altered wheats have potential to reduce the risk of chronic diseases and may be especially helpful in preventing or controlling type-II diabetes by slowing the postprandial rise in blood glucose.

Furthermore, because the starch present in the modified wheats was digested more slowly and less extensively, foods made from these novel wheats had a reduced energy density and may promote satiety. Accordingly, they may be effective in the prevention and management of obesity. They may have applications in the treatment or control of certain diseases and medical conditions e.g. enteral formulations to promote bowel health and function, nutritional products for assisting with blood glucose control in type-I diabetics or those at risk from this disease.

Example 14 Treatment or Prevention of Medical Conditions

Dysglucaemia

In addition to improving bowel health, the invention provides methods and compositions which are thought to be suitable for the promotion of euglycaemia and the treatment, prevention or reduced risk of disordered blood glucose regulation. This is based on the observed reduction in the potential glycemic index of foods incorporating the altered wheat starch. This may be useful in both healthy subjects such as athletes and in compromised individuals such as patients undergoing surgery or chemotherapy. In particular, it may be of great use in diabetic patients seeking to maintain optimal blood glucose levels during the day or night. Blood glucose levels in individuals may be disturbed or altered by exercise, pharmaceutical or surgical therapy, by disease or a syndrome involving multiple diseases or metabolic disorders. Examples include athletes, patients weakened by chemotherapy, fasting patients and patients suffering from disease or disorders disturbing or altering glucose metabolism, or patients undergoing treatment of such and other diseases or disorders. Further examples include animals other than humans such as, for example, pets, livestock or racehorses.

The methods or compositions may be used for improved glycaemic control, that is, for stabilising the blood sugar levels and alleviating the oscillation between unhealthy high and low blood sugar levels. Lack of glycaemic control is associated inter alia with microvascular damage such as occurs in diabetic retinopathy, diabetic ketoacidoses or so called diabetic coma.

A current method of treatment is to use uncooked cornstarch which provides a level of resistant starch. However, it is difficult to prepare compositions of uncooked cornstarch having an agreeable taste and texture, suitable for long-term daily consumption and therefore compliance is affected. Thus, there are advantages in treating diabetic hypoglycaemia by administering the altered wheat starch as described herein, containing resistant starch, as a slow release carbohydrate source for maintenance of acceptable levels of blood glucose in diabetic patients during the night, or at other times when intake of food at short intervals is not possible.

Thus the starch might be administered in a composition that is soluble in the small intestine. Suitable substances included in the composition with the altered wheat starch include polymers such as gum arabica, potassium alginate, guar gum, methyl cellulose, ethyl cellulose, liquid oils, liquid and hard fats and waxes such as paraffin, hydrogenated cottonseed oil, beeswax and carnauba wax.

Uremia

In kidney failure there is a decrease in the glomerular filtration rate and the kidneys are unable to maintain homeostasis of the blood. Retention of water causes oedema and the concentration of hydrogen ions may increase, acidosis may develop, nitrogenous wastes may accumulate and a condition referred to as uremia may develop in the blood and tissues. Examples of uremic toxins include ammonia, urea, creatinine, phenols, indoles, as well as larger molecules. The concentration of serum creatinine, blood urea nitrogen (BUN), uric acid, and guanidino compounds such as N-methyl guanidine (NMG) and guanidino succinic acid (GSA) are significantly altered.

Nitrogenous wastes such as urea, creatinine and uric acid, along with several other small and medium molecular weight compounds, flow into the small intestine and a number of attempts of treatment have been based on the use of the bowel as a substitute for kidney function. A number of absorptive compounds have been used for this purpose, as have locus bean gum. It is also thought that by increasing the fecal bulk and the production of SCFA that a beneficial effect can result. Short chain fatty acids acidify the intestinal content and via osmotic mechanism draw water into the intestinal lumen, providing a laxative effect, prevent overgrowth and facilitate ammonia and other waste nitrogen elemination. They also result in the growth of the fecal biomass, and in doing so, entrap urea and ammonia for bacterial protein synthesis or conversion to the ammonium ion. Through stimulation of bacterial growth and fermentation, prebiotic compounds such as high amylose starches also affect bowel habit and are mildly laxative.

Thus the invention provides altered wheat starch which may be used as a low cost supplement or treatment for renal insufficiency, liver insufficiency, inborn errors of urea metabolism or gastrointestinal disorders or diseases. A ready measure of the effect provided by the altered wheat starch can be determined by ascertaining the levels of serum creatinine.

Example 15 Determination of the Glycemic Index of Foods Made from Modified Wheat

The in vitro digestion and animal feeding trials indicated that food made with the modified wheat starch released glucose relatively slowly during digestion. To establish whether this would also be the case in humans, a feeding trial will be carried out in volunteers to measure the GI of the food and compare it to corresponding food made with wildtype starch. The GI ranks carbohydrate-containing human foods on a weight-for-weight basis according to their postprandial glycemic response. It has considerable clinical and practical utility which is well recognized worldwide. The particular aim of the study is to determine the glycemic index (GI) of two common bakery foods, a bread and muffin, made using modifed wholemeal flour. The study will assess the extent to which the modified foods raise blood glucose in volunteers relative to that of a reference carbohydrate and compare this with the GI values for the same type of bakery foods manufactured using standard wheat flour.

A standard wheat and the high amylose wheat will be milled and the resultant wholemeal flour baked into bread and muffins. All foods will be manufactured to industry standards by a commercial manufacturer. The amount of available carbohydrate in representative samples will be determined. The usual method for determining the amount of carbohydrate in foods is ‘by difference’, i.e. by subtracting the sum of the remaining components (protein, fat, water, ash and fiber) from 100. However, this approach is inherently less reliable than that obtained by direct analysis. Accordingly, we will determine the proximate composition of the test foods using accepted (AOAC) analytical techniques in order to calculate the available carbohydrate of our test foods.

Fourteen subjects will be recruited. GI is calculated using a dataset containing no less than 10 subjects and therefore commencing the trial with an additional 4 volunteers should be sufficient to account for possible withdrawals and the exclusion of outlier values. Prospective volunteers will be informed of the aims, methodology and risks of the trial and be asked to provide written consent.

Volunteers need to be between 16 and 65 years of age, not diabetic or suffering from haemophilia, renal or hepatic disease, not having a known food allergy, hypersensitivity or intolerance to cereal foods (eg celic sprue), are not taking medications known to influence glucose tolerance (oral contraceptives are excluded), and have a fasting blood glucose level between 3.5 and 6.0 mmol/l. In these respects, volunteers are normal and healthy. Persons considered by the investigator to be unwilling, unlikely or unable to comprehend or comply with the study protocol will be excluded, as will those who have participated in another research study within 30 days prior to the commencement of the proposed study. Prospective volunteers will be pre-screened on the basis of their fasting blood glucose levels between 3.5 and 6.0 mmol/l. Subjects whose fasting blood glucose is abnormally high will receive written notification advising them to undergo a glucose tolerance test and to consult their doctor.

Subjects are required to present at the clinic in the fasting state. Subjects are not permitted to consume food or drink, other than water, for a minimum of 10 hours before each test, have no alcohol or legumes on the previous evening, and must not undertake vigorous exercise immediately prior to or during the test. Two blood samples will be taken within 5 minutes of each other and analysed for glucose and the average result shall be taken as the baseline blood glucose concentration. Capillary (finger prick) whole blood will be collected on each occasion.

Specific quantities of the foods will be fed to the volunteers. Four wheat-based foods will be tested: a muffin and bread each made from modified wheat or standard wheat (both as wholemeal flour). The test and reference foods will be fed in random order. Glucose will be the reference food: 50 g of anhydrous glucose powder dissolved in 250 ml of water, and the amount of carbohydrate is exactly equal to that of the test food portion. The reference food is to be tested in each subject three times on separate days within the immediate 3-month period surrounding the testing of the breads and muffins. The test food will contain 50 g of glycemic (available) carbohydrate and volunteers will be instructed to eat the foods within a period of 12 min to 15 min. Subjects shall consume all the test or reference food at an even pace within 12 min to 15 min. They will be given 250 ml of water to consume with the food. During testing, subjects shall rest.

The change in blood glucose concentration over the next two-hours will be monitored according to the standardised protocol for testing the GI, based on the method published by FAO/WHO (1998). Blood samples are taken at 15, 30, 45, 60, 90 and 120 min, starting immediately after the first mouthful of food is taken. Samples are tested in duplicate for glucose. Duplicates should not vary by more than 0.3 mmol/l and additional blood samples may be required so that the CV is <3%. Blood glucose will be determined using a spectrophotometric technique which has an inter-assay co-efficient variation on standard solutions of <3.0%.

GI is determined as the glycemic response, measured as the incremental area under the blood glucose response curve after consumption of a standard amount (usually 50 or 25 g of carbohydrate, in this trial 50 g) of the test food, expressed as a percentage of the average glycemic response (IAUC) to an identical amount of carbohydrate from a reference food (glucose) consumed by the same subject on a separate occasion.

Calculations

The blood glucose response curve (concentration versus time) is plotted and the area under the curve calculated geometrically by applying the trapezoid rule. The area beneath the fasting concentration is ignored in the calculation of GI. Glucose is used as the reference food and by definition has a GI of 100. GI of the test food for an individual

${subject} = {\frac{{Integrated}\mspace{14mu}{area}\mspace{14mu}{of}\mspace{14mu}{glucose}\mspace{14mu}{response}\mspace{14mu}{curve}\mspace{14mu}{for}\mspace{14mu}{Test}\mspace{14mu}{food}}{{Integrated}\mspace{14mu}{area}\mspace{14mu}{of}\mspace{14mu}{glucose}\mspace{14mu}{response}\mspace{14mu}{curve}\mspace{14mu}{for}\mspace{14mu}{Reference}} \times 100}$

GI of the Test Food=Mean GI of ≧10 volunteers.

Analysis of variance will be used to determine whether foods made from modified wheat have a significantly lower GI. The wholemeal foods made from the standard wheat are expected to have quite a high GI (>70) whereas the corresponding foods containing modified wheat are expected to register a lower GI, less than or equal to 69, most likely less than 60.

Example 16 Determination of the Resistant Starch Content of Cereal Products in Human Volunteers

Resistant starch (RS) is starch which resists upper gut digestion and enters the large bowel. Quantitatively, it is a major source of fermentable substrate for the colonic microflora, which convert starch to metabolites believed critical to the health and metabolic welfare of the large bowel wall. In particular, bacterial fermentation of certain types of resistant starch favour production of SCFA such as butyrate, a major organic acid which is attracting considerable attention because of its capacity to promote programmed cell death and related processes that may protect against colon cancer by eliminating cells that have become dysfunctional.

To test whether the modified wheat having elevated amylose is less susceptible to digestive breakdown in the upper gut, a feeding trial will be carried out in human ileostomy subjects. In particular, the study will accurately determine the resistant starch content of typical foods prepared from high amylose wheat flour. The only effective way to measure resistant starch in foods in humans (in vivo) is to use volunteers with a permanent and well-functioning ileostomy. The ileostomy model technique is widely regarded as a reliable approach for assessing upper gut assimilation of dietary constituents.

The protocol is straightforward and simply involves feeding a number of healthy ileostomists the various test foods made from high amylose wheat or the corresponding low amylose wheat as a control. Recovery of starch and starch hydrolysates from the small bowel will then be determined using a standard analytical technique for total starch.

Volunteers will be recruited from an existing pool of subjects recruited previously or via stomal nurses at local hospitals. Subjects who may be included in the trial are aged 20-80 years, male or female, not receiving any medication likely to modulate small intestinal function or that could interfere with the study in the opinion of the investigator, do not have history of alcohol or drug abuse, have not used any experimental drug within 30 days of commencement of the study, and do not have gastrointestinal, renal, hepatic disease or intestinal inflammation. They must have had minimal terminal ileum removed (<10 cm) and have a conventional and well-functioning permanent ileostomy. They must be willing to comply with alcohol and diet restrictions in the study.

Exclusion criteria include: use of any form of drug therapy or medication or supplements on a regular basis that may interfere with bowel function, definite or suspected personal history or family history of adverse events or intolerance of starchy or other foods, pregnant women or sexually active female subjects able to conceive and practicing inadequate contraception, persons considered by the investigator to be unwilling, unlikely or unable to comprehend or comply with the study protocol and restrictions, persons unwilling or unable to collect ileal effluent as required, and subjects taking any supplements which could interfere with study parameters. Subjects will be asked to provide written consent after being provided with the appropriate information.

At least eight volunteers will be recruited. Statistical calculations reveal that a minimum of 6 subjects are required if there is to be an 80% chance of detecting a 200% increase in ileal starch excretion above baseline (α=0.05). Basal starch excretion for day 1 should be about 0.5 g. Consumption of a standard serving portion of a cereal product (˜60 g) made from modified cereal and containing 4% resistant starch is expected to yield an additional 2.4 g of starch at the terminal ileum. Therefore, on day 2, it is anticipated that total starch recovery will be in the order of nearly 3 g, a 5-fold increase over baseline.

Before the study commences, volunteers will be given detailed instructions about the study. Volunteers will carry out each study in their own homes. The study consists of a series of three 48-hour feeding trials over a period of 3 weeks. Volunteers will be on a low starch diet for two consecutive days (usually Tuesday and Wednesday) during which they collect the entire contents of their ileostomy bag at specified intervals, as described in detail below. The basal diet will be designed by a dietitian to be low in resistant starch and will be tailored to meet individual needs. Therefore, foods such as wholegrain breads, bananas, breakfast cereals, legumes and other foods that contain resistant starch, other than the test foods, will be avoided. On the second day they are also required to eat one of the test foods. Approximately 50-100 g of the cereal product (about a medium to large serving) will be eaten at 7:30 am on day 2.

Foods to be consumed for the study will be sourced from local supermarkets and delivered to the volunteers prior to the start of each study. Volunteers will prepare their own meals in accordance with detailed instructions. The modified cereal products will be produced by a commercial cereals manufacturer. Fluids (water, tea, coffee, but not alcohol) may be consumed freely by volunteers. Intake of the required foods will be closely monitored during the active phase of the study. Energy and macronutrient intake will be measured during study periods, estimated from food diaries. Meals will be eaten, and ileostomy bags emptied completely and contents collected, according to the following plan.

Day 1. Basal Diet.

Contents of ileostomy bag will be collected at 7 am and frozen on dry ice. The foods for the basal diet will be eaten for breakfast (7.30 am), morning tea (10.30 am), lunch (12.30 pm), afternoon tea (3.30 pm) and dinner (6.30 pm). Contents of the ileostomy bag will be collected at two hourly intervals after 7.00 am until 11 pm and frozen.

Day 2. Basal diet plus test food for breakfast. An identical pattern will be followed except that test foods (50-100 g) will be substituted for an equivalent amount of the basal diet.

Day 3. Collection of Ileostomy Bag Contents at 7.00 am.

At each sampling point, volunteers will dispense the entire contents of their ileostomy bags into appropriately labeled containers, which they then seal and place immediately into insulated coolers containing dry ice. Samples will be collected daily from the homes of volunteers and stored frozen (−20° C.) until analysis.

The assays to be carried out on ileal digesta are: output, which is the wet weight of each sample and daily output, moisture content, starch content, maltose content, glucose content, SCFA content and pH. Starch hydrolysates (free glucose & maltose) will be analysed because they originate from starch but have escaped digestion and are therefore a component of the resistant starch fraction.

Short-chain fatty acids and pH provide general information on the metabolic activity microflora of the distal small intestine. Ileal microbial activity in these individuals is a possible source of variation in starch digestibility.

An example of the basal diet is as follows:

Nutrients (Mean all Days) Energy: 8595.19 kJ Carbohydrate: 232.29 g Starch: 58.65 g Protein: 97.94 g Dietary Fibre: 19.11 g Total Fat: 84.06 g Total Sugars: 168.69 g Energy Ratios (Mean all Days) Protein: 20% Fat: 37% Carbohydrate: 44% Alcohol: 0% Fat Ratios (Mean all Days) Poly: 12% Mono: 38% Saturated: 51% Energ Ptn Fat Carb Fibre Sugar Stch Ml Food/Recipe Amnt Measure kJ g g g g g g juice, orange, commercial, ns 100.00 g 142 1 0 8 0 7 0 fruit salad, can-pear juice 200.00 g 354 1 0 20 3 17 0 milk, reduced fat, fortified 200.00 g 418 8 3 11 0 11 0 coffee powder, instant 1.00 tsp 4 0 0 0 0 0 0 sugar 5.00 g 84 0 0 5 0 5 0 cheese, cheddar 20.00 g 338 5 7 0 0 0 0 cracker, water 4.00 biscuit 291 2 2 12 0 0 12 water, plain, drinking 250.00 g 0 0 0 0 0 0 0 croissant 1.00 average 1066 6 15 23 2 3 20 ham, leg, non-canned, lean 50.00 g 226 9 2 0 0 0 0 salad 50.00 g 26 0 0 1 1 1 0 french dressing, commercial 20.00 g 220 0 5 2 0 2 0 custard, commercial 150.00 g 588 5 4 21 0 17 3 apple, stewed, added sugar 150.00 g 513 0 0 31 2 31 0 coffee powder, instant 1.00 tsp 4 0 0 0 0 0 0 biscuit, shortbread 3.00 biscuit 927 3 11 28 1 9 19 milk, reduced fat, fortified 50.00 g 104 2 1 3 0 3 0 sugar 5.00 g 84 0 0 5 0 5 0 chicken, breast, raw, lean 200.00 g 938 45 5 0 0 0 0 carrot, mature, peeled, boiled 100.00 g 112 1 0 6 4 6 0 broccoli, frozen, boiled 50.00 g 46 1 0 1 2 1 0 oil, canola 10.00 g 370 0 10 0 0 0 0 ice cream, vanilla 50.00 g 400 2 6 10 0 10 0 apricot, can-pear juice 150.00 g 266 1 0 14 3 12 0 chocolate, milk 50.00 g 1075 4 14 31 0 28 3 Total: 8595 98 84 232 19 169 59

Discussion

A variable fraction of the starch that is eaten is not broken down in the upper alimentary tract. The undigested (resistant) starch enters the colon (large bowel) where it has a number of purported benefits, which are largely effected through the actions of the complex assemblage of bacteria that inhabit that region of the gut. In utilising starch, colonic bacteria elaborate organic acids which serve a variety of critical health-related functions. These include providing a much needed energy source for cells lining the bowel, promoting and controlling gut mucosal growth, and halting proliferation of cells that have undergone neoplastic transformation. For individuals on diets considered to be high risk for colorectal cancer and certain other serious degenerative diseases of the large bowel, these benefical bacterial metabolites are often in short supply. Population studies have shown that the incidence of large bowel cancer diminishes with increased starch consumption (and by implication, resistant starch). The protective effect of resistant starch in this regard appear to be greater than that of dietary fibre. Systemic health also appears to benefit from resistant starch, however in this case the benefits are mediated through its physiological actions in the small bowel. By consuming foods rich in resistant starch, energy intake and glycemic index are reduced. Weight loss may also be facilitated through a resistant starch-induced increase in basal metabolic rate.

In humans, small intestinal digestion appears to be the rate limiting step in starch assimilation, and it is essentially governed by several key physiological factors, the most important of which are mastication and small intestinal digesta transit. Resistant starch is clearly a physiological entity—it is a product of a variety of physiological processes acting in concert. As such it is not an innate physical constituent of starchy foods.

Example 17 Production and Breeding of SSIIa Mutant Wheat

Durum wheat containing null SSIIa mutations in both of the A and B genomes (double-null durum wheat) or hexaploid wheat containing null SSIIa mutations in each of the A, B and D genomes (triple-null hexaploid wheat) in elite germplasm with favourable genetic backgrounds were developed in a breeding program. Detection of the mutations in plants of the breeding populations was achieved by using marker assisted selection as follows.

Nucleotide sequences of the A-, B- and D-genome homoeologous SSIIa genes of hexaploid wheat have been reported in WO00/66745, the contents of which are hereby incorporated by reference. The three genes are highly similar, being about 97% identical in the protein coding regions in pairwise comparisons of the nucleotide sequences. FIG. 10 shows a comparison of the cDNA nucleotide sequences corresponding to the three genes. Intron regions of the genes are more divergent (Li et al., 1999, Li et al, 2003). Molecular markers may be developed based on any of the polymorphisms between the homoeologs and ideally distinguish each of the three genes in hexaploid wheat, two genes in durum wheat. This was exemplified for a triple-null hexaploid wheat as follows.

Three groups of primer pairs were designed (Table 2), each pair being specific for the D-, B-, or A-genome SSIIa homoeolog. Group 1 primer pairs were specific for the D-genome, Group 2 for the B genome, and Group 3 for the A genome SSIIa genes. Genomic DNA was isolated from young wheat leaves of a triple-null SSIIa mutant hexaploid wheat (SGP-1) and a control line (cv. Sunco), collected when plants had grown to about the 10 leaf stage, using the Fast DNA Kit (Q-BIO gene). Each of the primer pairs were tested in PCR reactions using the genomic DNAs as template and the amplification products analysed on agarose gels. PCR reactions (20 μl) used 100 ng genomic DNA, 1.5 mM MgCl₂, 0.125 mM for each dNTP, 10 pmol primers, and 2 Units of Hotstar Taq polymerase (QIAGEN). PCR reactions used a thermal sequencer (Corbett Research, Sydney) with 1 cycle of 95° C. for 5 minutes, 35 cycles of 95° C. for 30 seconds, 60° C. for 30 seconds, and 72° C. for 2 minutes.

TABLE 13 Group 1 Primers (D genome SSIIa specific): JKSS2P1F: 5′ CCAAAAAAAAAATAGAAAAGAGG 3′ [SEQ ID NO. 15] JKSS2P1R: 5′ AACAACCAAGGACGAACG 3′ [SEQ ID NO. 16] JKSS2P2F: 5′ TCCTTGGTTGTTGGTCTCATTGCC 3′ [SEQ ID NO. 17] JKSS2P2R: 5′ AGCACGCTGGAAAGCGGG 3′ [SEQ ID NO. 18] JKSS2P3F: 5′ TTTCCAGCGTGCTCGCCC 3′ [SEQ ID NO. 19] JKSS2P3R: 5′ AACAATTCGTGAGCGAGACGACG 3′ [SEQ ID NO. 20] JKSS2P4F: 5′ ATCATCGTCGTCTCGCTCAC 3′ [SEQ ID NO. 21] JKSS2P4R: 5′ CACGGGCTCCTCGAAACC 3′ [SEQ ID NO. 22] JKSS2P5F: 5′ GAAATACATTGGTTTCGAGGAGCCC 3′ [SEQ ID NO. 23] JKSS2P5R: 5′ TGATGGTGTGGTTATCAGCCTCC 3′ [SEQ ID NO. 24] JKSS2P6F: 5′ GAAGGAGGCTGATAACCACACC 3′ [SEQ ID NO. 25] JKSS2P6R: 5′ CATAGTCCCCATAGGTTGGTACC 3′ [SEQ ID NO. 26] JKSS2P7F: 5′ GCTTTCTATCTTAGGTTGTGGTACCAAGG [SEQ ID NO. 27] 3′ JKSS2P7R: 5′ CAATTCGCGGTGAAGAGAACATGG 3′ [SEQ ID NO. 28] JKSS2P8F: 5′ ACCTTACATGCACATTTGGTCAAGCG 3′ [SEQ ID NO. 29] JKSS2P8R: 5′ CATACGGAAAATGCACCGTATGGC 3′ [SEQ ID NO. 30] JKSS2P9F: 5′ GTGTGCCATACGGTGCATTTTCC 3′ [SEQ ID NO. 31] JKSS2P9R: 5′ GGTATGGGCTCCCAAGTAGC 3′ [SEQ ID NO. 32] JKSS2P10F: 5′ TAGCCGGACCGTTATAGAAGGC 3′ [SEQ ID NO. 33] JKSS2P10R: 5′ CTGGCTAAGTACTGTGTGTGGG 3′ [SEQ ID NO. 34] JKSS2P11F: 5′ GACCCACACACAGTACTTAGCC 3′ [SEQ ID NO. 35] JKSS2P11R: 5′ CGTGATCCAAATCCTCTTGCGC 3′ [SEQ ID NO. 36] JKSS2P12F: 5′ CAAGAGGATTTGGATCACGGGC 3′ [SEQ ID NO. 37] JKSS2P12R: 5′ CCAAAGCATGTAATTCGGCATGTCAG 3′ [SEQ ID NO. 38] JKSS2P13F: 5′ GCACCACCGGTGCATTTTTACC 3′ [SEQ ID NO. 39] JKSS2P13R: 5′ ATGATCTCCACGCCCTTCTGC 3′ [SEQ ID NO. 40] JKSS2P14F: 5′ AGAAGGGCGTGGAGATCATCG 3′ [SEQ ID NO. 41] JKSS2P14R: 5′ CATATACCTCCGCTCTACTCTGC 3′ [SEQ ID NO. 42] JKSS2P15F: 5′ TGAGACGCTGATTCCAATCCGG 3′ [SEQ ID NO. 43] JKSS2P15R: 5′ TCTTTGGATTGGACGGTGACGTG 3′ [SEQ ID NO. 44] Group 2 Primers (B genome SSIIa specific): JKSS2BP1F: 5′ TGCGTTTACCCCACACAGAGCA 3′ [SEQ ID NO. 45] JKSS2BP1R: 5′ GCGCGGCGTCGTCGAT 3′ [SEQ ID NO. 46] JKSS2BP2F: 5′ CAGGAGGACGCCCGTCT 3′ [SEQ ID NO. 47] JKSS2BP2R: 5′ GAATCGTGATTCTGGTGGTGTTCG 3′ [SEQ ID NO. 48] JKSS2BP3F: 5′ CCAAGGATGATGGCTGGGCTGTT 3′ [SEQ ID NO. 49] JKSS2ABP3R: 5′ TCTTCGCCAAAGCCTTGGGCAA 3′ [SEQ ID NO. 50] JKSS2ABP5F: 5′ TCCTCTCTTCCGACACCGC 3′ [SEQ ID NO. 51] JKSS2BP5R: 5′ GCCGCATGGAACGTGCCAT 3′ [SEQ ID NO. 52] JKSS2BP7F: 5′ GCGGACCAGGTTGTCGTC 3′ [SEQ ID NO. 53] JKSS2BP7R: 5′ ACGGTGTCCCTCAGGCCA 3′ [SEQ ID NO. 54] JKSS2BP8F: 5′ ACCGTCCCCGTCGTGCAT 3′ [SEQ ID NO. 55] JKSS2BP8R: 5′ GATCGTTGCCCTCTGTAATAATGCAC 3′ [SEQ ID NO. 56] Group 3 Primers (A genome SSIIa specific): JKSS2AP1F: 5′ GACCAACCCGCGCATCGT 3′ [SEQ ID NO. 57] JKSS2AP1R: 5′ CGGCGTCGTCGTCGAC 3′ [SEQ ID NO. 58] JKSS2AP2F: 5′ AAGGTGGCGCGCCGG 3′ [SEQ ID NO. 59] JKSS2AP2R: 5′ TGCCAAAGGTCCGGAATCATGG 3′ [SEQ ID NO. 60] JKSS2AP3F: 5′ GATGATGCGGGCTCCTTTGAACAT 3′ [SEQ ID NO. 61] JKSS2ABP3R: 5′ TCTTCGCCAAAGCCTTGGGCAA 3′ [SEQ ID NO. 62] JKSS2ABP4F: 5′ GTACCAAGGTATGGGGACTATGAG 3′ [SEQ ID NO. 63] JKSS2ABP4R: 5′ GCCCCCATAAATGTCTTCCTGG 3′ [SEQ ID NO. 64] JKSS2ABP5F: 5′ TCCTCTCTTCCGACACCGC 3′ [SEQ ID NO. 65] JKSS2AP5R: 5′ GCCGCATGGAACGTGCCAA 3′ [SEQ ID NO. 66] JKSS2ABDP6F: 5′ GTTCCATGGCACGTTCCATGC 3′ [SEQ ID NO. 67] JKSS2ABDP6R: 5′ CTGGTGCGCGATGTTATGTATCAC 3′ [SEQ ID NO. 68] JKSS2AP7F: 5′ ACTGTACGACCCCGTGGGTGGTGAG 3′ [SEQ ID NO. 69] JKSS2AP7R: 5′ TGCCGTAGGCCATGGCGTAA 3′ [SEQ ID NO. 70] JKSS2AP8F: 5′ CGTGCGGGTTGAACCAGCTT 3′ [SEQ ID NO. 71] JKSS2AP8R: 5′ GCCCTTTGCCTCCGACTTAACAA 3′ [SEQ ID NO. 72]

Using the 15 Group 1 primer pairs, only the reaction with primers JKSS2P7F and JKSS2P7R revealed a polymorphism in fragment size between the triple-null mutant and Sunco. A fragment of 675 bp was amplified from Sunco genomic DNA and two PCR fragments (675 bp and about 600 bp) were amplified from the triple-null wheat DNA. The PCR fragments were purified and their nucleotide sequences determined. This showed that the shorter PCR fragment contained a 63 bp deletion which derived from the D genome SSIIa gene in the triple-null mutant. The deletion corresponds to nucleotide positions 3834 to 3896 in the SSIIa genomic sequence (Accession No. AY133248).

When the Group 2 and 3 primer pairs were used, differences were also observed between the triple-null mutant and Sunco. Primer pair JKSS2BP7F and JKSS2BP8R amplified one fragment of approximately 1000 bp from Sunco genomic DNA while a longer fragment of approximately 1150 bp was amplified from the triple-null wheat DNA. Sequencing of the fragments showed that the longer PCR fragment contained a 175 bp insertion relative to the shorter fragment. The longer fragment was from the B genome SSIIa gene of the triple-null wheat. The insertion was at a position between nucleotides 1906 and 1907 in the B-genome SSIIa gene reported in WO00/66745.

When the primer pair JKSS2BP1F and JKSS2AP2R was used, a fragment of about 1150 bp was amplified from Sunco DNA while a shorter DNA fragment of approximately 900 bp was amplified from the triple-null wheat DNA. Nucleotide sequencing showed that there was a 289 bp deletion in the A genome SSIIa gene of the triple-null wheat. The deletion included the first 254 nucleotides of the sequence in the A genome SSIIa gene (Accession No. AF155217) and extended to 35 nucleotides upstream of this sequence.

The positions of the mutations in the SSIIa genes are shown schematically in FIG. 11. The presence of relatively large insertions or deletions into the SSIIa genes fully explained the null phenotype of each allele since the mutations disrupted the protein coding regions of the genes and would have resulted in truncation of the proteins on translation or the absence of any translation. The null phenotypes were confirmed by the absence of individual isoforms of the SSIIa (SGP-1) proteins when analysed on SDS-PAGE.

Other combinations of the forward and reverse primers described above were tested in order to optimise discrimination between the wild-type and null SSIIa alleles. The optimal primer pairs were designated Group 4 primers. Representative gel electrophoretograms for PCR reactions using these primer pairs are shown in FIG. 12. The genome allocation of these mutations was confirmed by using nullisomic/tetrasomic lines for the 7A, 7B and 7D chromosomes in the Chinese Spring background. Using these lines, the PCR reactions were shown to be genome specific.

Group 4 primers: Optimal primer pairs for the detection of SSIIa mutations in A, B and D genomes in wheat A genome: JKSS2BP1F: 5′ TGCGTTTACCCCACACAGAGCA 3′ [SEQ ID NO. 73] JKSS2AP2R: 5′ TGCCAAAGGTCCGGAATCATGG 3′ [SEQ ID NO. 74] B genome: JKSS2BP7F: 5′ GCGGACCAGGTTGTCGTC 3′ [SEQ ID NO. 75] JLTSS2BPR1: 5′ CTGGCTCACGATCCAGGGCATC 3′ [SEQ ID NO. 76] D genome: JLTSS2D3: 5′ GTACCAAGGTATGGGGACTATGAA 3′ [SEQ ID NO. 77] JLTSS2D4: 5′ GTTGGAGAGATACCTCAACAGC 3′ [SEQ ID NO. 78]

These primers were subsequently used routinely for the screening of the SSIIa null mutations in breeding populations. Because they were co-dominant markers, they could readily be used to detect the presence of the SSIIa mutations in heterozygotes.

Marker Assisted Breeding with SSIIa Mutants

A cross was carried out between the elite hexaploid wheat variety Sunco and the triple-null SSIIa mutant (SGP-1, Yamamori et al., 2000). Double haploid plants were produced from 170 F1 plants and each screened for the presence of the SSIIa mutations using the diagnostic primer pairs described above and genomic DNA isolated from the plants. The presence or absence of the individual mutations were confirmed on 100 of the lines using the SDS-PAGE method for separation of the SSIIa protein isoforms from endosperm as described (Yamamori et al., 2000). The two methods were completely consistent for genotyping the plants. All eight of the possible genotypes for the SSIIa alleles (ABD, aBD, AbD, ABd, abD, aBd, Abd, abd, lower case representing the null alleles) were identified in the population at about the expected frequencies.

Representative plants of each genotype were grown and grain harvested for analysis of the starch produced in the grain and feeding trials as described below.

The three progenitor lines Chousen 57 (A genome null), Kanto 79 (B genome null) and Turkey 116 (D genome null) used to produce the triple-null wheat (Yamamori 2000) were each crossed with wheat cultivars Sunco and Hume to transfer the SSIIa null mutations to Australian elite wheat. Progeny of these crosses and subsequent backcrosses were screened with the PCR markers described above to determine the presence of the null alleles in heterozygotes. The backcross lines containing the null alleles were crossed to combine the three alleles.

In a similar fashion, the progenitor lines Chousen 57 (A genome null) and Kanto 79 (B genome null) were crossed with durum wheat cultivar Wallaroi to transfer the SSIIa null mutations to this elite durum wheat. The F1 generation of plants containing A and B-genome null alleles for SSIIa were generated and will be selfed to produce homozygous double-null durum wheat mutants. The breeding lines have been confirmed by using the PCR markers.

Example 18 Characteristics of Starch from SSIIa Null Hexaploid Wheat

Starch was extracted from 40 doubled haploid lines (Example 18) representing all of the eight possible genotypes for the SSIIa alleles (Table 13). Starch was isolated from the five triple-null samples (abd) by the protease extraction method of Morrison et al., 1984, followed by water washing and removal of the tailings. Starch was isolated from the remaining 35 samples by first making a dough and separating starch from gluten using a Glutoniatic 2200 (Perten Instruments) followed by extensive water washing and removal of the tailings.

TABLE 14 Doubled haploid lines for SSIIa used in starch characterisation study. Geno- Geno- Geno- Sam- Geno- type Sample type Sample type ple type Sample ABD A1 AbD A3 abD A21 Abd A13 A113 A8 A24 A31 B32 B46 A30 A51 B70 B54 A50 B40 E18 C19 C13 D20 aBD A2 ABd A88 aBd A37 abd A7 B60 B34 B56 B23/24 B69 E28 D5 B29 C20 E42 E26 B48 F30 F5 E45 B63

Granule Morphology and Size Distribution

Triple-null lines (abd) of the hexaploid wheat showed altered starch granule morphology, showing irregular shaped granules, and abnormal crystallinity as seen by a loss of birefringence under polarized light compared to wild-type lines (ABD). These observations were consistent with those of Yamamori et al (2000). Single null lines (aBD, AbD, ABd) and double null hexaploid wheat lines (abD, aBd, Abd) showed similar granule morphology and crystallinity to the wild type lines. Granule size distribution as measured on the starch slurries showed a typical bimodal particle size distribution for both the wild-type and triple-null samples, with a trough between the peaks at about 6.6 μm diameter. The triple-null sample had 12% of the smaller B granules, defined as having a size of less than 6.6 μm diameter, while the wild-type had 16%. The single and double null samples showed similar results (16-18% B granules) to the wild type.

Starch Characteristics

Triple-null lines showed a slight increase in amylose content (39% of the starch) compared to wild-type lines (33%) when measured by the iodine method. Single null lines and double null lines showed similar amylose contents (31-34%) to the wild type lines.

When the chain length distribution was determined, the number of amylopectin chains with degrees of polymerization (DP) of 6-10 was increased in the starch from the triple-null mutant while the frequency of DP 11-25 chains decreased. The frequency of chain lengths DP7 and 8 were both increased by at least 3%. Single and double null lines showed intermediate chain length distributions, with the single null lines being closer to the wild type lines and the double null lines, especially those with null b allele, being closer to the triple-null lines. This suggested that the wild-type B allele contributed more to the phenotype than the A or D alleles.

Typical starch pasting profiles of the samples are shown in FIG. 13A. Triple null samples do not paste well following the RVA temperature-time profile used and give the flattest curves compared with the wild type. The single and double null samples give intermediate profiles.

Average RVA peak viscosity results for the eight genotypes are shown in FIG. 13B. Triple null lines showed the lowest peak viscosity results (106) and wild type lines showed the highest peak viscosity results (232). The remaining null lines showed intermediate results, with the single null results (165-172) being closer to the wild type, and the double null results (119-132) being closer to the triple null results. Similar trends were observed for the other RVA parameters: holding strength, breakdown, final viscosity, setback).

When average swelling power data were obtained, starch from triple-null grain showed the lowest swelling power figures (7.5) while wild-type starch showed the highest swelling power results (12.5). The single and double null lines showed intermediate results, with the single null results (11) being closer to the wild type, and the double null results (9) being closer to the triple null results.

Gelatinisation properties as measured by the DSC showed differences between the different genotypes for SSIIa (FIG. 14). Wild-type starch samples showed the highest gelatinisation temperature range with a peak gelatinisation temperature of approximately 61.5° C. and the largest enthalpy, of about 4.2 J/g. Triple-null starch samples showed the lowest gelatinisation temperature range with a peak gelatinisation temperature of approximately 55° C. and the lowest enthalpy of about 1.9 J/g. The peak gelatinization temperature was thus decreased by more than 6° C. compared to wild-type starch. Single and double null starch samples gave intermediate results. DSC assay also gave results for the amylose-lipid dissociation endotherm. Little difference was observed between the different genotypes for SSIIa for the temperature at which the second peak occurred.

Conclusions

The mutant plants that had single, double or triple null SSIIa alleles produced starch having different properties compared to starch from plants expressing three wild-type alleles. The dosage of the mutant alleles was important in determining the extent of the change in starch properties. Three mutant alleles had to be present (triple null) for significant change to occur in amylose content, granule size distribution or granule morphology. However, for the other starch properties measured, there was an additive effect of individual null alleles or mutations, with greater effect with increasing number of mutant alleles. This suggests that all three wild-type alleles contribute to the starch phenotype, with possibly the B-genome allele having the greatest effect of the three.

Example 19 Animal Trial with SSIIa Wheat

A feeding trial was carried out in rats using modified wheat starch in the form of flour obtained from the SSIIa mutant wheat described in Example 18. The trial was carried out using the procedure essentially as described in Example 11. The trial compared a diet containing the SSIIa wheat flour to a control diet containing flour from cultivar Janz. In addition, low and high amylose maize starch, and high amylose barley starch diets were compared. The diets were formulated according to Table 15.

TABLE 15 Formulation of the experimental diets Low Control SSIIa amylose High High wheat mutant maize amylose amylose Component (Janz) wheat (3401C) maize barley 3401C (maize flour)* 243 259 414 176 227 Casein 142 96 173 236 110 Sucrose 110 117 104 106 102 Safflower oil 50 38 51 52 29 Wheat bran (fibre 156 13 221 214 0 source) High amylose wheat 0 435 0 0 0 (SSIIa) Low amylose wheat 260 0 0 0 0 (Janz) High amylose maize 0 0 0 178 0 (Hi-maize) Vitamin & mineral 39 42 37 37 37 premix^(†) *Conventional (low-amylose) starch (3401C) (Penford Australia Pty Ltd, Lane Cove NSW). ^(†)Pharmamix P169 (Propharma Australia Pty Ltd, Dandenong, Victoria) which contained, per kg mix, 1.5 g retinyl acetate, 25 mg cholecalciferol, 20 g α-tocopherol, 2 g riboflavin, 7.5 mg cyanocobalamin, 5.6 g Ca pantothenate, 50 mg biotin, 10 g nicotinamide, 1 g menadione, 50 g FeSO₄ · 7H₂O, 10 g MnO₂, 50 g ZnO, 5 g CuSO₄ · 7H₂O, 0.25 g CoSO₄, 0.5 g KI, 0.1 g Na₂SeO₄, and 31 g antioxidant (Oxicap E2; Novus Nutrition, Melbourne Australia).

Rats had unrestricted access to treatment diets and drinking water for 28 days. During the last 5 days, the animals were kept in individual metabolism cages to allow accurate estimation of feed and water intake and total collection of faeces which were retained for analysis. Rats were observed daily and weighed weekly. Diet consumption of rats when housed individually in metabolism cages was recorded daily, as was the weight of faeces.

Feed Intake and Body Weight Gain

Weights of the rats at the start of study were similar among the various dietary groups (188±1 g; overall mean±sem; n=40). Rats gained about 159±5 g during the 27-day dietary treatment period, equivalent to about 6.1±0.2 g/d. There were minor differences between some groups, with rats fed the SSIIa diet gaining more weight and having a higher live weight at the end of study than those on the 3401C diet (both P<0.05; Table 16). All diets were well accepted and food consumption, which averaged 18.9±0.4 g/d during the 5-d metabolism cage phase of the study, was similar among groups (Table 17).

TABLE 16 Live weight and growth rate of rats during the study¹ Live weight (g) Weight gain (g)² Treatment Start End Experiment Group Janz 190 353^(ab) 164^(ab) 152 SSIIa 189 369^(a) 179^(a) 168 3401C 188 331^(b) 143^(b) 134 Hi-Maize 187 343^(ab) 155^(ab) 145 Pooled SEM 3  12  10 9 ¹Values are means and their pooled se for 8 rats per dietary treatment. Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05) ²Weight gain for the entire 28-d treatment period (Experiment) and for the first 21 days during which rats were maintained in groups of approximately 4 animals.

TABLE 17 Voluntary food consumption and feed conversion ratio of rats during the metabolism cage phase of the study¹ Feed intake² Weight gain² Feed conversion Treatment (g) (g) efficiency³ Janz 95.2 12 12.3 SSIIa 97.7 11 10.8 3401C 90.5 9 8.8 Hi-Maize 91.4 11 11.0 Pooled SEM 4.1 3 2.7 ¹Values are means and their pooled se for 8 rats per dietary treatment. Treatments did not differ (P > 0.05). ²Total amount of food consumed and increase in live weight for the 5-day period in which rats were maintained in metabolisms cages. ³Calculated as (weight gain/feed intake) × 100.

Blood Lipids, Insulin and Glucose

Diet had no effect on circulating levels of total cholesterol or lipoproteins, however plasma triacylglycerol concentration was lower for Hi-maize (P<0.05) and tended to be lower for the SSIIa diet compared to Janz (P=0.09; Table 18). Elevated blood triglycerides levels are a risk factor for cardiovascular disease. Surprisingly, circulating insulin concentration was 45% lower for rats fed the SSIIa diet compared to those on the Janz diet. Serum glucose concentrations were unaffected by the dietary treatments.

TABLE 18 Plasma lipids, insulin and glucose on the final day of study Treatment TC HDL LDL TAG Insulin Glucose Janz 2.27 1.74 0.53 2.90^(a) 0.84^(a) 9.25 SSIIa 2.19 1.76 0.43 2.08^(ab) 0.46^(ab) 9.38 3401C 2.05 1.67 0.38 2.25^(ab) 0.71^(ab) 10.02 Hi-Maize 1.98 1.63 0.35 1.66^(b) 0.58^(ab) 9.94 Pooled SEM 0.19 0.14 0.09 0.33 0.18 0.30 ¹Values are means and their pooled se for 8 rats per dietary treatment. Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05).

Intestinal Weights

Diet had a marked effect on intestinal tract growth (Table 19). The SSIIa diet elicited greater caecal tissue growth compared to rats fed Janz wheat and the magnitude of the response was similar to that of Hi-maize. These differences are still evident when the data were expressed on a live weight basis (Table 20) suggesting that the SSIIa and Hi-maize diets had a direct trophic effect on the gut. Rats fed the SSIIa diet also tended to have a slightly heavier small bowel, about 12% heavier than rats fed Janz (P 0.08).

TABLE 19 Dimensions of the small and large intestines¹ Small Small Caecum Colon Colon intestine intestine weight length weight Treatment length (cm) weight (g) (g) (cm) (g) Janz 102.1 8.2^(ab) 2.5^(a) 13.9^(a) 2.6^(a) SSIIa 97.6 9.1^(bc) 4.3^(b) 14.5^(ab) 2.8^(a) 3401C 106.6 7.6^(a) 2.3^(a) 13.7^(a) 2.4^(a) Hi-Maize 100.6 7.9^(a) 4.7^(b) 13.5^(a) 2.4^(a) Pooled SEM 3.8 0.4 0.5 0.6 0.3 ¹Values are means and their pooled se for 8 rats per dietary treatment, except for colon weight of rats fed the Janz diet where n = 7. Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05).

Intestinal Digesta Mass and Moisture Content, and Faecal Output

The mass of wet digesta present in the various intestinal compartments of rats fed the SSIIa diet was between 24-62% greater than that in controls, but only for the small bowel was the difference in digesta weight statistically significant (P=0.007; Table 21). The colon contained about 50% more digesta for rats on the SSIIa diet compared to those fed Janz (P=0.08). Consumption of the SSIIa diet resulted in wetter luminal contents throughout much of the large bowel compared to controls (Table 22). In the distal colon and caecum, digesta moisture levels were 10% and 4% higher, respectively, for the SSIIa treatment compared to Janz (P<0.001 and 0.05). Although the contents of the proximal colon also contained more water, the difference did not quite reach significance (P=0.07).

TABLE 22 Water content of large bowel digesta¹ Digesta water content (g/100 g) Treatment Caecum Proximal colon Distal colon Janz 78.7^(a) 75.2^(ab) 65.4^(a) SSIIa 81.6^(b) 80.0^(abc) 72.2^(b) 3401C 78.3^(a) 74.3^(bc) 65.5^(a) Hi-Maize 80.1^(ab) 79.1^(bc) 79.7^(c) Pooled SEM 0.7 1.4 1.9 ¹Values are means and their pooled se for 8 rats per treatment group except for the following: for proximal colonic digesta, n = 7 for 3401C, SSIIa and Hi-maize; for distal colonic digesta, n = 7 for Janz, SSIIa and Hi-maize. Values in the same column with different superscripts differ (P < 0.05). Values in the column without superscripts are not different (P > 0.05).

Large Bowel Digesta and Faecal pH

The SSIIa diet produced more acidic luminal conditions relative to the Janz diet throughout most of the large bowel except for the distal colon (Table 23). Generally, faecal and digesta pH were similar for the Hi-maize and SSIIa diets except in the proximal colon where the pH was lower for Hi-maize (P=0.02).

TABLE 23 pH of digesta and faeces collected on the final day of study Digesta and faecal pH Treatment Faeces Caecum Proximal colon Distal colon Janz 6.32^(a) 6.90^(a) 6.83^(a) 6.44^(ab) SSIIa 5.78^(b) 6.68^(b) 6.38^(b) 6.41^(ac) 3401C 6.41^(a) 7.04^(a) 6.78^(a) 6.65^(a) Hi-Maize 5.68^(b) 6.51^(b) 6.03^(c) 6.34^(bc) Pooled SEM 0.16 0.06 0.09 0.08 ¹Values are means and their pooled se for 8 rats per treatment group except for the following: for pH of proximal digesta, n = 7 for 3401C and SSIIa, and n = 6 for Hi-maize; for distal colonic digesta, n = 7 for Janz, SSIIa and Hi-maize. Values in the same column with different superscripts differ (P < 0.05).

Large Bowel and Faecal SCFA

Generally, major individual and total SCFA concentrations and pools in the caecum of rats fed the SSIIa diet were similar to those on the Janz diet (Table 24, 25). There were indications that SSIIa may have stimulated propionate production, with molar proportions of this organic acid 38% greater for the SSIIa than Janz (P=0.07). Although Hi-maize increased caecal propionate concentration compared to Janz, butyrate concentration was actually reduced by feeding this particular maize starch. The pronounced digesta bulking action of Hi-maize resulted in larger caecal SCFA pools of all individual SCFA, except for butyrate, compared to Janz (and SSIIa).

In the proximal colon, concentrations of individual and total SCFA were similar in rats fed the SSIIa and Janz diets (Table 26), however pools of propionate and total SCFA were more than 100% greater for the former compared to the latter treatment (Table 27). The caecal butyrate pool was >200% larger on the SSIIa diet relative to Janz, but the difference was not quite statistically significant (P=0.10). The effects of the SSIIa diet on levels of SCFA in the proximal colon were generally similar to those of Hi-maize.

The SSIIa diet produced greater concentrations and pools of total SCFA in the distal colon compare to Janz (Table 28 and 29), and the effects were similar to those of Hi-maize (all P>0.05). Digesta propionate concentration and molar ratio were greater for SSIIa compared to Janz, (P<0.01 and 0.05, respectively; Table 28). Distal colonic pools of acetate and propionate were about 100% (P<0.05) and more than 200% larger (P<0.01) for rats fed the SSIIa diet compared to those on the Janz diet (Table 29). Hi-maize raised the propionate pool in the distal colon (relative to Janz and 3401C, both P<0.05) but had no effect on pools of either acetate or butyrate. The total SCFA pool tended to be larger for SSIIa than Hi-maize (P=0.056).

Concentrations of acetate, propionate and total SCFA in faeces collected on the final day of study were higher for the SSIIa treatment compared to Janz (Table 30). The SSIIa diet produced similar faecal SCFA concentrations to Hi-maize. There were no significant effects of SSIIa on faecal SCFA excretion relative to the controls (Table 31). Faecal propionate output was about 140% greater on the SSIIa diet compared to Janz but the difference did not attain significance (P=0.09).

Water Balance, and Urinary Large Bowel Phenols

There were only minor differences in water intake and urine volume among the various treatment groups (Table 32). Phenol urine concentration and excretion were each about 30-40% lower on the SSIIa diet compared to Janz, but these differences were not significant (P=0.12 and 0.095, respectively). Cresol concentration and excretion was similar for SSIIa and Janz treatments. Hi-maize had little influence on urinary phenols but cresol excretion was lower for this treatment compared to SSIIa. Phenol concentrations were 65% lower in the caecum of rats fed SSIIa compared to Janz (Table 33). Both SSIIa and Hi-maize had similar actions in lowering large bowel digesta and faecal concentrations of phenol and p-cresol however the magnitude of the response of the former dietary treatment was generally greater.

TABLE 32 Urine output and phenol and cresol content and excretion on the final day of study¹ Water Urine Concentration Excretion intake volume (umol/L) (umol/d) Treatment (mL) (mL) Phenol Cresol Phenol Cresol Janz 21.1^(ab) 5.2^(a) 25.6^(ab) 50.9^(b) 139.9^(a) 255.5^(ab) SSIIa 23.4^(a) 5.1^(a) 17.2^(bc) 59.9^(b) 85.7^(bc) 309.4^(a) 3401C 19.1^(b) 4.7^(ab) 27.9^(a) 28.8^(b) 123.5^(ab) 143.3^(b) Hi-Maize 20.5^(ab) 3.9^(ab) 10.7^(cd) 63.2^(b) 40.8^(cd) 225.5^(ab) Pooled 1.2 0.5 3.6 15.3 17.7 56.1 SEM ¹Values are means and their pooled se for 8 rats per treatment group. Values in the same column with different superscripts differ (P < 0.05).

The data show conclusively that numerous indices of large bowel fermentation were all significantly higher in rats fed the modified wheat compared with those fed the standard wheat, consistent with an elevated level of RS and lower glycemic impact. Thus large bowel digesta wet weight and SCFA pools and faecal SCFA excretion were usually higher in rats fed the modified wheat compared with those fed the control diet. pH values were also significantly lower, again consistent with greater fermentation. That these differences were due to starch, and not NSP, was ensured by balancing the fibre content of the diets. This is of some interest in view of the apparent importance of SCFA in promoting large bowel function.

TABLE 20 Dimensions of small and large bowel normalised to live weight¹ Small intestine² Caecum² Colon² Length Weight Weight Length Proximal wt Distal wt Colon wt Treatment (cm/g) (g/g) (g/g) (cm/g) (g/g) (g/g) (g/g) Janz 29.1^(ab) 2.31^(a) 0.71^(a) 3.97^(a) 0.25^(ab) 0.16^(a) 0.73^(a) SSIIa 26.6^(a) 2.47^(a) 1.17^(b) 3.95^(a) 0.22^(a) 0.15^(a) 0.76^(a) 3401C 32.4^(b) 2.28^(a) 0.69^(a) 4.17^(ab) 0.23^(a) 0.15^(a) 0.72^(a) Hi-Maize 29.4^(ab) 2.32^(a) 1.39^(b) 3.92^(a) 0.22^(a) 0.16^(a) 0.69^(ab) Pooled 1.5 0.08 0.11 0.18 0.01 0.01 0.07 SEM ¹Values are means and their pooled se for 8 rats per dietary treatment, except for colon weight of rats fed the Janz diet where n = 7. Values in the same column with different superscripts differ (P < 0.05). Calculated as: (unit measurement × 100/final live weight).

TABLE 21 Wet weight of digesta in small and large intestine, and faecal output on final day of study Intestinal digesta weight (g) and faecal output (g/d) Small Proximal Distal Total Treatment intestine Caecum colon Colon colon Faeces Janz 1.81^(a) 1.57^(a) 0.39^(a) 0.57 0.97^(a) 3.98^(a) SSIIa 2.54^(b) 1.94^(a) 0.63^(ab) 0.81 1.44^(ab) 4.01^(a) 3401C 1.48^(a) 1.15^(a) 0.43^(a) 0.63 1.06^(a) 3.46^(a) Hi-Maize 1.75^(a) 3.29^(b) 0.49^(a) 0.58 1.07^(a) 4.51^(a) Pooled SEM 0.19 0.44 0.13 0.13 0.21 0.47 ¹Values are means and their pooled se for 8 rats per dietary treatment. Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05).

TABLE 24 Individual major and total short chain fatty acid concentrations and molar ratios in caecal digesta Short chain fatty acid concentration (mmol/L) Molar ratio Treatment Acetic Propionic Butyric Total Acetic Propionic Butyric Janz 62.1^(ab) 14.8^(ab) 44.7^(a) 125.5^(a) 49.6^(a) 11.7^(a) 35.6^(a) SSIIa 56.8^(b) 19.2^(b) 37.3^(ab) 117.5^(a) 47.8^(a) 16.2^(b) 32.1^(a) 3401C 62.5^(ab) 16.1^(bc) 37.7^(ab) 119.8^(a) 52.1^(a) 13.3^(ab) 32.6^(ab) Hi-Maize 70.5^(a) 28.9^(c) 23.3^(b) 130.3^(a) 54.2^(a) 22.2^(c) 21.5^(b) Pooled SEM 4.6 2.1 4.6 6.3 3.1 1.3 3.5 ¹Values are means and their pooled se for 8 rats per dietary treatment. Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05).

TABLE 25 Individual major and total short chain fatty acid pools in caecal digesta Short chain fatty acid pool (mmol) Treatment Acetic Propionic Butyric Total Janz 77^(a) 18^(a) 57^(ab) 157^(a) SSIIa 80^(a) 27^(a) 56^(ab) 169^(a) 3401C 55^(a) 14^(a) 34^(a ) 107^(a) Hi-Maize 187^(b)  77^(b) 74^(b  ) 344^(b) Pooled SEM 28  7 12   36 ¹Values are means and their pooled se for 8 rats per dietary treatment. Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05).

TABLE 26 Individual major and total short chain fatty acid concentrations and molar ratios in proximal colonic digesta Short chain fatty acid concentration (mmol/L) Molar ratio Treatment Acetic Propionic Butyric Total Acetic Propionic Butyric Janz 42.7 9.0^(a) 16.0^(a) 69.6^(ab) 61.5^(a) 12.6^(a) 23.1^(ab) SSIIa 44.6 14.0^(bc) 25.4^(a) 86.9^(b) 54.7^(a) 16.5^(ab) 25.9^(a) 3401C 44.1 10.7^(b) 24.3^(ab) 81.8^(b) 54.8^(a) 13.4^(a) 28.8^(a) Hi-Maize 50.5 16.4^(d) 13.2^(ab) 81.3^(b) 63.8^(ab) 20.3^(b) 14.5^(b) Pooled SEM 4.3 1.7 4.9 8.8 3.6 1.4 3.7 ¹Values are means and their pooled se for 8 rats per dietary treatment except for SSIIa and Hi-maize where n = 7, and for 3401C where n = 6. Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05).). Values in columns without superscripts are not different (P > 0.05).

TABLE 27 Individual major and total short chain fatty acid pools in proximal colonic digesta Short chain fatty acid pool (mmol) Treatment Acetic Propionic Butyric Total Janz 12^(a) 2^(a)  5^(a) 20^(a) SSIIa 23^(ab) 7^(bc) 15^(b) 47^(b) 3401C 18^(a) 5^(ab)  9^(ab) 32^(ab) Hi-Maize 22^(ab) 7^(bc)  7^(ab) 36^(ab) Pooled SEM  5 1  3  9 ¹Values are means and their pooled se for 8 rats per dietary treatment, except for SSIIa and Hi-maize where n = 7, and for 3401C where n = 6. Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05).

TABLE28 Individual major and total short chain fatty acid concentrations and molar ratios in distal colonic digesta Short chain fatty acid concentration (mmol/L) Molar ratio Treatment Acetic Propionic Butyric Total Acetic Propionic Butyric Janz 57.2 13.0^(a) 40.7^(a) 114.7^(ab) 50.1^(a) 11.4^(a) 35.3^(a) SSIIa 69.0 26.2^(b) 41.1^(a) 140.0^(b) 49.0^(a) 18.5^(bc) 29.8^(a) 3401C 47.6 13.9^(a) 34.1^(a) 99.4^(ab) 49.6^(a) 14.1^(ab) 33.1^(a) Hi-Maize 62.5 27.8^(b) 33.8^(a) 127.8^(b) 48.8^(a) 21.9^(c) 26.3^(a) Pooled SEM 7.5 2.5 5.7 11.7 2.5 1.6 3.4 ¹Values are means and their pooled se for 8 rats per dietary treatment, except for distal colonic digesta, n = 7 for Janz, SSIIa and Hi-maize.). Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05).

TABLE 29 Individual major and total short chain fatty acid pools in distal colonic digesta Short chain fatty acid pool (mmol) Treatment Acetic Propionic Butyric Total Janz 24^(ab)  6^(a) 18^(a) 49^(a) SSIIa 48^(c) 18^(c) 25^(a) 93^(ab) 3401C 21^(a)  6^(a) 15^(a) 44^(a) Hi-Maize 32^(abc) 14^(bc) 18^(a) 65^(ab) Pooled SEM  6  2  4 10 ¹Values are means and their pooled se for 8 rats per dietary treatment, except for distal colonic digesta where n = 7 for Janz, SSIIa and Hi-maize. Values in the same column with different superscripts differ (P < 0.05).

TABLE 30 Individual major and total short chain fatty acid concentrations and molar ratios in faeces collected on final day of study Short chain fatty acid concentration (mmol/L) Molar ratio Treatment Acetic Propionic Butyric Total Acetic Propionic Butyric Janz 76.0^(ab) 8.0^(a) 3.8 89.6 85.2^(a) 8.7^(a) 4.1^(ab) SSIIa 98.0^(a) 15.5^(b) 3.6 118.2 83.0^(ab) 12.8^(b) 3.2^(a) 3401C 72.6^(b) 11.1^(ab) 3.4 88.5 82.0^(ab) 12.5^(b) 3.9^(ab) Hi-Maize 86.9^(ab) 16.0^(b) 5.7 111.9 79.8^(b) 14.1^(b) 5.0^(ab) Pooled SEM 8.3 2.4 1.1 10.9 1.7 1.1 0.9 ¹Values are means and their pooled se for 8 rats per dietary treatment. Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05).

TABLE 31 Individual major and total short chain fatty acid faecal excretion on the final day of study Short chain fatty acid pool (mmol) Treatment Acetic Propionic Butyric Total Janz 162^(ab) 17^(a)  8^(ab) 190^(a) SSIIa 235^(bc) 41^(ab)  8^(ab) 287^(ab) 3401C 147^(a) 22^(ab)  7^(a) 172^(a) Hi-Maize 249^(c) 46^(b) 18^(b) 316^(b) Pooled SEM  30  9  3  41 ¹Values are means and their pooled se for 8 rats per dietary treatment. Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05).

TABLE 33 Phenol and cresol content of large bowel digesta and faeces on the final day of study¹ Phenol concentration (umol/g) Cresol concentration (umol/g) Proximal Distal Proximal Distal Treatment Caecum colon colon Faeces Caecum colon colon Faeces Janz 2.97^(a) 1.96 1.52^(ab) 4.54^(a) 1.05 2.80^(a) 6.62^(a) 12.57^(a) SSIIa 1.03^(b) 1.12 0.93^(bc) 2.85^(a) 1.23 3.02^(a) 5.67^(a) 8.36^(ab) 3401C 3.44^(a) 2.36 2.02^(a) 4.06^(a) 0.30 0.61^(b) 1.52^(b) 4.92^(b) Hi-Maize 0.38^(b) 1.90 0.56^(bc) 0.95^(b) 1.39 0.57^(b) 3.89^(ab) 3.53^(b) Pooled 0.36 1.22 0.34 0.65 0.52 0.66 1.21 1.81 SEM ¹Values are means and their pooled se for 8 rats per dietary treatment, except for proximal colonic digesta where n = 5 for Janz, and n = 7 for SSIIa). Values in the same column with different superscripts differ (P < 0.05). Values in columns without superscripts are not different (P > 0.05).

Example 20 Production of Breads With SSIIa Wheat

Bread was made using the flour obtained from the SSIIa wheat in various formulations as follows. The methods used were essentially the same as those described in Example 12. Micro Z-arm mixing, mixograms and micro extension testing were performed as described in Example 12.

The bread recipe used, based on the 13.0 g flour as 100% was as follows: flour 100%, salt 2%, dry yeast 1.5%, vegetable oil 2%, and improver (ascorbic acid 100 ppm, fungal amylase 15 ppm, xylanase 40 ppm, soy flour 0.3%, obtained from Goodman Fielder Pty Ltd, Australia) 1.5%. The water addition level was based on the micro Z-arm water absorption values that were adjusted for the fill formula. Flour and the other ingredients were mixed to peak dough development time in a 35 g Mixograph. The moulding and panning were carried out in a two staged proofing steps at 40° C. at 85% RH. Baking was carried out in a Rotel oven for 15 min at 190° C. Loaf volume (determined by the seed (canola) displacement method) and weight measurements were taken after cooling on a rack for 2 hours. Net water loss was measured by weighing the loaves over time.

Results.

Small scale (10 g dough mass) bread-making trials were carried out using flour obtained by milling samples of grain from the eight genotypes obtained from the Sunco x SSIIa deficient triple-null mutant as described in Example 18. The mixing times and water absorption characteristics of each of the doughs obtained from the modified wheat were measured (Table 34). The mixing times were within a range considered acceptable for commercial bakery applications. Water absorption rates were generally correlated with the number of SSIIa null alleles, in particular for the abd genotype. Flour from the abd genotypes required significantly higher amounts of water to be added to achieve 500BU consistency in the micro Z-arm mixer. The water absorption results may have reflected the influence of the altered starch granule size and shape on water absorption characteristics. However, other changes in the grain such as the starch structure or gelatinization temperature may also have affected water absorption. On examination of the viscosity profiles from the RVA, it was noticed that, for the given optimum water absorptions, the modified wheat flour dough was less viscous than the standard flour dough.

TABLE 34 Mixing time and water absorption measurements for doughs made with wheat flour from various SSIIa genotypes. Sample SSIIa Water No. Genotype Mixing Time (min) Absorption (%) A1 ABD 2 64.6 A2 abD 2.16 62.8 A24 abd 2.48 77.6 A51 Abd 2 65.0 A8 AbD 1.37 67.1 B23/24 abd 3.2 93.7 B29 abd 2.44 93.7 B48 ABd 2.53 95.8 B54 ABD 2.01 59.2 B56 aBd 2.17 62.4 C13 abD 2.36 63.5 C19 AbD 2.3 63.1 D31 ABD 1.5 57.7 D5 aBd 2.36 61.5 E18 ABd 3.14 62.3 E26 ABd 2.37 62.8 E27 aBd 2 63.6 E28 AbD 2.19 56.0 E4 Abd 2.48 64.2 E42 ABd 2.1 61.0 F5 Abd 2.42 75.2 A30 abD 2 60.7 B60 aBD 1.21 57.8 SSIIa abd 2 97.0

The specific volumes for loaves made with the flours were also determined, and the data are shown in FIG. 15. These data show that the addition of triple-null wheat flour reduced loaf volume. The breads made with the single or double-null SSIIa wheat flours had acceptable loaf volumes and these flours could be used in standard white bread applications. The bread containing triple-null flour produced loaves having reduced volumes and therefore this flour is better suited for heavier style breads such as wholemeal or mixed grain breads. It was thought that further manipulation of improvers, gluten addition, and/or alteration to the genetic background of the wheat variety would ameliorate the observed reduction in loaf volume. In particular, the viscosity of the dough mix, which is an important feature for end-product quality, was noted to be on the low side; this could be improved by reducing the water content of the dough.

These studies showed that breads with commercial potential, including acceptable crumb structure, texture and appearance, were obtained using the modified wheat flour samples. Furthermore, the SSIIa-deficient wheats may be provided in combination with preferred genetic background characteristics (e.g. preferred high and low molecular weight glutenin matrix), the addition of improvers such as gluten, ascorbate or emulsifiers, or the use of differing bread-making styles (e.g. sponge and dough bread-making, sour dough, mixed grain, or wholemeal) to provide a range of products with particular utility and nutritional efficacy for improved bowel and metabolic health. The flour or wholemeal may be blended with flour or wholemeal from non-modified wheats or other cereals such as barley to provide desired dough and bread-making or nutritional qualities. For example, flour from cvs Chara or Glenlea has a high dough strength while that from cv Janz has a medium dough strength. In particular, the levels of high and low molecular weight glutenin subunits in the flour is positively correlated with dough strength, and further influenced by the nature of the alleles present.

Example 21 Examples of Other Foods Containing Modified Wheat

Modified wheat, made from grain reduced in one or more SBEII or SSIIa activities and therefore having elevated amylose and resistant starch contents, could be incorporated in other foods to provide lower GI or increased RS. A typical recipe for muesli bars is as follows:

-   -   125 g butter, margarine or 56 g canola oil     -   ½ cup brown sugar     -   ½ cup castor sugar     -   2 tablespoon honey     -   2 cups rolled modified wheat (rolled oats in control)     -   3 cups dry whole-wheat breakfast cereal equivalent (for example,         cornflakes, crushed Weetbix, rice bubbles, unprocessed bran or         mixtures thereof)     -   1 cup shredded coconut     -   1 cup dried fruit (raisins, peaches, pears, apricots and apples         or mixtures)     -   ¼ banana chips     -   ¼ cup chopped cashew nuts     -   ¼ cup sunflower seeds     -   ¼ cup sesame seeds

Directions:

Preheat oven to 175° C. Grease an 11×7 inch baking pan. In medium sauce pan, over low heat, combine butter or margarine, sugars and honey. Cook with stirring until butter or margarine is melted and sugar is dissolved. Remove from heat. Add modified wheat, nuts, coconut and sesame seeds etc. Mix with a wooden spoon until well combined. Press mixture evenly into the prepared baking pan. Bake for 15 to 18 minutes in the preheated oven, until the top is golden brown. Let cool in the pan and cut into bars.

Muesli bars were made with high amylose barley, M292 (Morell et al., 2003) instead of the modified wheat according to the recipe above. Moisture contents of 4%, 6% or 8% were trialled, varying the baking time at 15, 12.5 and 10 min. In subsequent in vitro RS analyses (Example 22), it was noted that there was an inverse correlation between the moisture content and the level of the RS in the product when using a constant level of barley as ingredient. Moisture content of 4% was therefore preferred. The barley can readily be substituted with the modified wheat to produce muesli bars with relatively low GI or high RS.

TABLE 35 Composition of muesli bars at 4% moisture % of total Ingredients Weight (g) ingredient Canola Oil 56.00 8.0% water 28.00 4.0% Brown Sugar 56.00 8.0% Castor Sugar 56.00 8.0% Honey 70.00 10.0% Modified wheat 140.00 20.0% Rice Bubbles 52.50 7.5% Puffed Wheat (Honey Weets) 52.50 7.5% Coconut (shredded) 56.00 8.0% Fruit dried apricots 66.50 9.5% Fruit dried sultanas 66.50 9.5% Total Ingredient Weight 700 100.0%

A typical recipe for low GI/high RS muffins made with modified wheat is as follows:

-   -   1¾ cups regular flour     -   ¾ cup wholemeal flour from SSIIa-null wheat     -   1 tablespoon baking powder     -   ½ teaspoon salt     -   2 large eggs, at room temperature     -   ⅓ cup honey     -   ¾ cup milk (whole, low-fat, or nonfat) or more to suitable         moisture content.     -   ⅓ cup canola oil or other vegetable oil     -   2 teaspoons vanilla extract     -   Fillings e.g. chocolate chips, apple and cinnamon.

Directions:

-   -   1. Preheat the oven to 190° C. Spray muffin tins with nonstick         spray or line with paper muffin cups.     -   2. Whisk the whole meal flour, regular flour, baking powder and         salt in a medium bowl until well combined. Set aside.     -   3. In a large bowl, whisk the eggs until lightly beaten, then         whisk in the honey until smooth, about 30 seconds. Whisk in the         milk, oil, and vanilla. Finally, stir in the prepared flour         mixture until incorporated.     -   4. Fill the prepared tins three-quarters full. Use additional         greased tins or small, oven safe, greased ramekins for any         leftover batter, or reserve the batter for a 10 second baking.         Bake for 22 minutes, or until the muffins have rounded, cracked         tops and a toothpick inserted in the center of one muffin comes         out with a few moist crumbs attached.     -   5. Cool the muffins for 5 minutes more on the rack before         serving.

TABLE 36 Ingredients Table Batter % of total Ingredients Baking % Weight (g) ingredient Calculation Numbers 404%  600 100.00% Cake flour 100%  148.43 24.74% SSIIa wholemeal flour 81% 120.01 20.00% Baking powder  5% 7.07 1.18% Salt  1% 1.48 0.25% Eggs 48% 70.68 11.78% Honey 60% 89.06 14.84% Milk 70% 103.90 17.32% Canola oil 35% 52.30 8.72% Vanilla extract  5% 7.07 1.18%

Example 22 In Vitro Measurements of Glycemic Index (GI) and Resistant Starch (RS) of Food Samples

The Glycemic Index (GI) and resistant starch (RS) content of food samples including the bread made as described in Example 20 was measured in vitro essentially as described in Example 13.

The GI and RS content of breads made with the modified wheat flour from the Sunco x SSIIa (triple null SSIIa) lines were determined, including all eight possible combinations of SSIIa alleles. As controls, breads were also made from the SSIIa triple-null mutant, high amylose wheat (WO2005/001098) and commercial bread made with added high amylose maize starch (Wonderwhite) and similarly tested. Thus, the contribution of each of the null alleleles for the SSIIa gene on the A, B and D genomes could be assessed, singly and in each of the possible combinations, for effect on RS and GI. The results of the in vitro GI and RS measurements are shown in FIGS. 7 and 8.

The level of RS increased in proportion to the number of SSIIa mutant alleles present and in the doubled-haploid progeny was highest for the triple-null genotype, although the RS was not as high as for the bread made with the high amylose wheat flour. These levels were higher than in commercially available bread (Wonderwhite) containing high amylose corn starch (“Hi-Maize”) used at 10% in the formulation, which had less than 2% RS. Furthermore, the maximum level of corn starch that can be incorporated in bread without affecting its quality is limited to about 10-12%. Therefore, the use of SSIIa mutant wheat in the production of breads provided significant advantages including the level of RS that could be achieved.

The rate of in vitro starch hydrolysis (GI) was reduced significantly, to below 50%, for the bread made with the triple null SSIIa wheat compared to the bread made with the wild-type wheat. The GI results for breads made from wheat containing one or two null alleles in SSIIa genes, having partial or incomplete suppression of SSIIa, were similar to the wildtype control. Surprisingly, the GI of the bread made from the triple null samples was as low as that of the bread made with the high amylose wheat flour (65-80% amylose), even though the percentage amylose in the starch was less than 40%.

Example 23 Determination of the Glycemic Index of Foods Made from SSIIa Wheat

The in vitro digestion and animal feeding trials indicated that food made with the SSIIa modified wheat starch released glucose relatively slowly during digestion. To establish whether this would also be the case in humans, a feeding trial will be carried out in volunteers to measure the GI of the food and compare it to corresponding food made with wildtype starch. The methods used will essentially be as described in Example 15. The wholemeal foods made from the standard wheat are expected to have quite a high GI (>70) whereas the corresponding foods containing SSIIa modified wheat are expected to register a lower GI, less than or equal to 69, most likely less than 60 or even less than 55.

REFERENCES

-   Abel et al., (1996). The Plant Journal 10: 981-991. -   Anderson et al., (1989). Nucl Acids Res 17 : 461-462. -   Baba et al., (1991). Biochem Biophys Res Commun 181: 87-94. -   Batey and Curtin. (1996). Starch 48: 338-344. -   Batey et al., (1997). Cereal Chemistry 74: 497-501. -   Becker et al., (1994). Plant J. 5: 299-307. -   Blauth et al., (2001). Plant Physiology 125: 1396-1405. -   Bourque. (1995). Plant Science 105: 125-149. -   Boyer and Preiss, (1978). Carbohydrate Research 61: 321-334. -   Boyer and Preiss, (1981). Plant Physiology 67: 1141-1145. -   Boyer et al., (1980). Starch 32: 217-222. -   Buleon et al., (1998). International Journal of Biological     Macromolecules 23:85-112. -   Cao et al., (1999). Plant Physiol 120: 205-215. -   Cao et al., (2000). Archives. of Biochemistry and Biophysics. 373:     135-146. -   Case et al., (1998). Journal of Cereal Science 27: 301-314. -   Cheng et al., (1997). Plant Physiol 115: 971-980. -   Craig et al., (1998). Plant Cell 10: 413-426. -   Denyer et al. (1996). Plant Physiology 112: 779-785. -   Ewen and Pusztai (1999). Lancet 354: 1353-1354. -   Feldman. pp 3-56 in The World Wheat Book, A history of wheat     breeding. Eds Bonjean and Angus, Lavoisier Publishing, Paris. -   Fergason. 1994. pp 55-77 in “Speciality Corns” eds, CRC Press Inc. -   Fisher et al., (1993). Plant Physiol 102:1045-1046. -   Fisher et al., (1996). Plant Physiol 110: 611-619. -   Fuwa et al., (1999). Starch/Starke. 51: 147-151. -   Gao et al., (1997). Plant Physiol 114: 69-78. -   Gao et al., (1998). Plant Cell 10: 399-412. -   Giroux and Hannah. (1994). Molecular and General Genetics 243:     400-408. -   Green et al., (1997). Plant Physiology 114: 203-212. -   He et al., (1994). Plant Cell Reports 14: 192-196. -   Hedman and Boyer, (1982). Biochemical Genetics 20: 483-492. -   Hess et al., (1990). Plant Science 72: 233-244. -   James et al., (1995). Plant Cell 7: 417-429. -   Jobling et al., (1999). Plant Journal 18: 163-171. -   Komari et al., (1996). Plant Journal 10: 165-174. -   Konik-Rose et al (2001) Starch 53: 14-20. -   Krueger et al., (1987). Cereal Chemistry 64: 187-190. -   Kubo et al., (1999). Plant physiology. 121: 399-409. -   Li et al., (1999a). Plant physiology. 120: 1147-1155. -   Li et al., (1999b). Theoretical and Applied Genetics 98: 1208-1216. -   Li et al., (2000). Plant Physiology 123: 613-624. -   Li et al., (2003). Funct Integr Genomics 3: 76-85. -   Libessart et al., (1995). Plant Cell 7: 1117-1127. -   McCreery and Helentjaris (1994). Methods in Molecular Biology, Vol.     28: Protocols for nucleic acid analysis by non-radioactive probes,     67-71, Humana Press Inc., Totawa, N.J. -   Mizuno et al., (1993). Journal of Biological Chemistry 268:     19084-19091. -   Mizuno et al., (1992). Journal of Biochemistry 112: 643-651. -   Morell et al., (1997). Plant Physiology 113: 201-208. -   Morell et al., (1998). Electrophoresis 19: 2603-2611. -   Morell et al., (2003). Plant J. 34: 173-185. -   Morrison and Laignelet (1983). Journal of Cereal Science 1: 9-20. -   Morrison et al., (1984) J. Cereal Sci. 2:257-271. -   Mullins et al., (1999). European Journal of Plant Pathology 105:     465-475. -   Myers et al., (2000). Plant Physiology 122: 989-997. -   Nakamura (2002). Plant Cell Physiology 43: 718-725. -   Nakamura and Yamanouchi (1992). Plant Physiol 99: 1265-1266. -   Nair et al., (1997). Plant Sci 122: 153-163. -   Nehra et al., (1994). Plant J. 5: 285-297. -   Ng et al., (1997) Cereal Chemistry 74: 288-292. -   Nishi et al., (2001). Plant Physiology 127: 459-472. -   Rahman et al., (1995). Australian Journal of Plant Physiology 22:     793-803. -   Rahman et al., (1997). Genome 40: 465-474. -   Rahman et al., (1999). Theor Appl Genet. 98: 156-163. -   Rahman et al., (2000). J Cereal Sci 31: 91-110. -   Rahman et al., (2001). Plant Physiol 125: 1314-1324. -   Repellin et al., (1997). Plant Gene Reg 97-094 -   Schulman and Kammiovirta, (1991). Starch 43: 387-389. -   Senior (1998). Biotechnology and Genetic Engineering Reviews 15:     79-119. -   Shannon and Garwood, (1984). In Starch: Chemistry and Technology,     Whistler et al., eds, Academic Press, Orlando, Fla., pp 25-86. -   Shure et al., (1983). Cell 35 : 225-233. -   Sidebottom et al., (1998). Journal of Cereal Science 27: 279-287. -   Slade et al. (2005). Nat Biotech. 23: 75-81. -   Stacey and Isaac (1994). Methods in Molecular Biology, Vol. 28:     Protocols for nucleic acid analysis by non-radioactive probes, pp     9-15, Humana Press Inc., Totawa, N.J. -   Sun et al., (1997). The New Phytologist 137: 215-215. -   Sun et al., (1998). Plant Physiol 118: 37-49. -   Takeda et al., (1993a). Carbohydrate Research 240: 253-262. -   Takeda et al., (1993b). Carbohydrate Research 246: 273-281. -   Thomas and Atwell 1999 Starches Eagen Press, St Paul, Minn., USA pp:     13-24. -   Thorbjornsen et al, (1996). Plant Journal 10: 243-250. -   Vasil et al., (1992). Bio/Technology 10: 667-674. -   Vasil et al., (1993). Bio/Technology 11: 1553-1558. -   Wang et al., (1998). Journal of Experimental Botany 49: 481-502. -   Weeks et al., (1993). Plant Physiol 102: 1077-1084. -   Wegener et al., 1994. Mol. Gen Genet. 245: 465-470. -   Weir et al., (2001). Aust J Plant Physiol 28: 807-818. -   Yamamori et al., (2000). Theor. Appl. Genet. 101: 21-29 -   Young. (1984). in Whistler et al. (eds), Academic Press, Orlando,     Fla., chap 8. -   Zhao and Sharp, (1998). Plant Breeding 117: 488-490. -   Zikiryaeva and Kasimov, (1972). Uzbekskii Biologicheskii Zhurnal     6:18-20. -   Zwar and Chandler, (1995). Planta 197: 39-48. 

1. A method for decreasing pH of bowel contents, increasing total short chain fatty acid (SCFA) concentration in the bowel contents, increasing total SCFA amount in the bowel contents, increasing concentration of one SCFA in the bowel contents or increasing the amount of one SCFA in the bowel contents, increasing fecal bulk in the bowel, increasing total water volume of the bowel contents, increasing total water volume of feces or reducing fecal levels of putrefactive products in the bowel contents in a mammalian animal, comprising the step of feeding the animal an effective amount of an altered wheat starch in the form of whole, milled, ground, pearled, rolled, kibbled, par-boiled or cracked grain of a wheat plant, wherein the proportion of amylose in the starch of the whole, milled, ground, pearled, rolled, kibbled, par-boiled or cracked grain of the wheat plant is 30% to 37% and wherein said grain comprises i) a reduced level of starch synthase IIa (SSIIa) enzyme relative to wild-type whole, milled, ground, pearled, rolled, kibbled, par-boiled or cracked grain; and ii) starch with a decreased gelatinisation temperature relative to the starch of wild-type whole, milled, ground, pearled, rolled, kibbled, par-boiled or cracked grain, as measured by differential scanning calorimetry.
 2. The method of claim 1, wherein said altered wheat starch is in the form of a food comprising said wheat grain, or wholemeal of the wheat grain.
 3. The method of claim 1, wherein the grain comprises one or more genetic variations, which genetic variations comprise one or more mutations in genes encoding SSIIa, or one or more introduced nucleic acids which encode inhibitors of expression of the genes encoding SSIIa.
 4. The method of claim 1, wherein the altered wheat starch or the starch of the grain comprises at least 2% resistant starch.
 5. The method of claim 1, wherein the wheat plant is a member of the genus Triticum that is capable of being intercrossed with Triticum aestivum ssp. aestivum or Triticum turgidum L. ssp. durum.
 6. The method of claim 1, wherein the altered wheat starch is provided to the animal in the form of milled, ground, pearled, rolled, kibbled, par-boiled or cracked grain.
 7. The method of claim 1, wherein the altered wheat starch is provided to the animal in the form of a food, beverage or pharmaceutical preparation.
 8. The method of claim 7, wherein the altered wheat starch is provided to the animal in the form of a food or beverage comprising an ingredient comprising said altered wheat starch, wherein said ingredient is flour, wholemeal, or semolina from said grain.
 9. The method of claim 7, wherein the altered wheat starch is provided to the animal in the form of a food or beverage comprising flour, wholemeal, semolina or starch from another source.
 10. The method of claim 7, wherein the altered wheat starch is provided to the animal in the form of a food or beverage, and the altered wheat starch is heated to a temperature of at least 60° C., for 10 min prior to or during the preparation of said food or beverage.
 11. The method of claim 1, wherein the animal is a human.
 12. The method of claim 11, wherein the amount of altered wheat starch fed to the human is 10 g per day.
 13. The method of claim 1, wherein the pH of the bowel contents is decreased and the total SCFA concentration in the bowel contents is increased.
 14. The method of claim 1, wherein the pH of the bowel contents is decreased and the total SCFA amount in the bowel contents is increased.
 15. The method of claim 1, wherein the pH of the bowel contents is decreased and the concentration of one SCFA in the bowel contents is increased.
 16. The method of claim 1, wherein the pH of the bowel contents is decreased and the amount of one SCFA in the bowel contents is increased.
 17. The method of claim 1, wherein the pH of the bowel contents is decreased.
 18. The method of claim 1 wherein said grain is non-shrunken.
 19. The method of claim 1, wherein the proportion of amylose in the starch of the grain is at least 35%.
 20. The method of claim 1 wherein said grain has an average weight of at least 36 mg.
 21. The method of claim 11, wherein the altered wheat starch or the starch of the grain comprises at least 2% resistant starch.
 22. The method of claim 11, wherein the wheat plant is a member of the genus Triticum that is capable of being intercrossed with Triticum aestivum ssp. aestivum or Triticum turgidum L. ssp. durum.
 23. The method of claim 11, wherein the altered wheat starch is provided to the animal in the form of milled, ground, pearled, rolled, kibbled, par-boiled or cracked grain.
 24. The method of claim 11, wherein the altered wheat starch is provided to the human in the form of a food, beverage or pharmaceutical preparation.
 25. The method of claim 24, wherein the altered wheat starch is provided to the human in the form of a food comprising an ingredient comprising said altered wheat starch, wherein said ingredient is flour or wholemeal from said grain.
 26. The method of claim 24, wherein the altered wheat starch is provided to the human in the form of a food or beverage comprising flour, wholemeal, semolina or starch from another source.
 27. The method of claim 24, wherein the altered wheat starch is provided to the human in the form of a food or beverage, and the altered wheat starch is heated to a temperature of at least 60° C. for 10 min prior to or during the preparation of said food or beverage.
 28. The method of claim 12, wherein the pH of the bowel contents is decreased and the total SCFA concentration in the bowel contents is increased.
 29. The method of claim 12, wherein the pH of the bowel contents is decreased and the total SCFA amount in the bowel contents is increased.
 30. The method of claim 12, wherein the pH of the bowel contents is decreased and the concentration of one SCFA in the bowel contents is increased.
 31. The method of claim 12, wherein the pH of the bowel contents is decreased and the amount of one SCFA in the bowel contents is increased.
 32. The method of claim 12, wherein the pH of the bowel contents is decreased.
 33. The method of claim 12, wherein the grain comprises a genetic mutation in each of three genes encoding SSIIa. 